Abstract Book - Rick Hansen Foundation
Transcription
Abstract Book - Rick Hansen Foundation
Abstract Book Vancouver Convention Centre rickhansen.com/i2012 Table of Contents Executive Summaries.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Order: Summaries are listed in order of appearance per the Interdependence 2012 Program. Only summaries received at the time of printing are included. Krassioukov, Andrei. Autonomic Dysfunctions and Sexual Health Following Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Wyndaele, Jean-Jacques. Advancements in the Management of Bladder and Male Sexual Function after Spinal Cord Lesion. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Zhou, Mouwang. Urodynamic Investigation after Spinal Cord Injury: One-Channel Cystometry vs. Multichannel Urodynamics.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Elliott, Stacy L. Sexual and Fertility Rehabilitation: What’s New and Productive. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Fehlings, Michael. Bioengineered Strategies to Promote Repair of the Injured Spinal Cord. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Fawcett, James. Targeting the Extracellular Matrix to Repair Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Tetzlaff, Wolfram. Dietary Strategies for Acute Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 McKerracher, Lisa. The Cethrinphase I/IIA Trial to Treat Acute Spinal Cord Injury: Update on Results.. . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Biering-Sørensen, Fin. Accelerating Progress Through Global Standards: The International Spinal Cord Injury Data Sets .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Hayes, Keith C. Implementation of Best Practices: A Multi-Layered Global Challenge. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Noreau, Luc. The SCI Community Survey: Toward a Better Understanding of Support Services that Enhance Community Living.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Martin Ginis, Kathleen A. Best Practices Implementation Through Community-University Partnerships. . . . . . . . . . . . . . . . . . . . . . . 11. Williams, Stephanie. Communicate, Collaborate, Cure... Networking Down Under .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Harrop, James S. Building and Maintaining a Multispecialist SCI Center.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Young, Wise. China SCI Net Clinical Trials. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Krassioukov, Andrei. Latest Advances in Evaluation of Autonomic Dysfunctions Following Spinal Cord Injury. . . . . . . . . . . . . . . . . . 13 Wecht, Jill M. The Presentation and Consequences of Decentralized Autonomic Cardiovascular Control in Persons with SCI. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Claydon, Victoria. The Influence of Injury to Autonomic Pathways on Cardiovascular Disease Risk after Spinal Cord Injury . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Bauman, William A. Metabolic and Endocrine Disorders in Individuals with Chronic Spinal Cord Injury: Predisposition to Cardiovascular Disease. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Kwon, Brian. The Challenge of Deciding What to Translate. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Curt, Armin. Preclinical Studies Provide Limited Prediction of Safety and Efficacy in human SCI trials. . . . . . . . . . . . . . . . . . . . . . . . 15 Grossman, Robert G. Organizational, Regulatory and Financial Barriers to Conducting Clinical Trials in SCI. . . . . . . . . . . . . . . . . . . 15 Guest, James D. Regulatory Considerations to Initiate an Invasive Experimental Treatment for Spinal Cord Injury. . . . . . . . . . . . . . 15 McKerracher, Lisa. The Importance of Innovation and Collaboration in Developing New Treatments for Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 1 Wirth III, Edward D. Clinical Translation of Absorbable Biopolymers and Hydrogels for Acute Spinal Cord Injury. . . . . . . . . . . . . . . 16 Kenneth Galbraith. Commercialization of SCI Research. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Lebkowski , Jane S. Achievements and Challenges in the Development of Human Embryonic Stem Cell Based Therapies. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Kurzweil, Ray. The Accelaration of Technology in the 21st Century: The Impact on Healthcare and Medicine.. . . . . . . . . . . . . . . . . 17 Prochazka, Arthur. Neuroprostheses and Tele-supervised Exercise to Improve Hand Function: Benefits and limitations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Harkema, Susan. Strategies for Neuromuscular Recovery after Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Peckham, P. Hunter. Institute for Functional Restoration, A New Model for Deployment. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 Kirshblum, Steven. Technological Advances in SCI .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 Spungen, Ann M. Walking with an Exoskeleton for Persons with Paraplegia . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Krassioukov, Andrei. Is There a Relationship Between Paralympic Classification, Autonomic symptoms and Altered Cardiovascular Control Among Elite Wheelchair Athletes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Warburton, Darren. Advancements in the Physiological Evaluation of the High Performance Paralympic Athlete. . . . . . . . . . . . . . . 19 West, Christopher. Cardiorespiratory limitations to Exercise Performance in Paralympic Athletes with Cervical Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Taunton, Jack. Paralympic Medical Services for the 2010 Paralympic Winter Games.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Phillips, Aaron A. Arterial Stiffness on Physically Active Individuals with Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 Wong, Shirley. Assessing Autonomic Completeness of Spinal Cord Injury: A Missing Piece of Paralympic Athlete Classification.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 Fehlings, Michael. Repair and Regeneration of the Injured Spinal Cord with Neural Stem Cells: “Hope or Hype”.. . . . . . . . . . . . . . 21 Guest, James D. Understanding the Challenges to Proving Efficacy with Cell Therapy in Clinical Subjects . . . . . . . . . . . . . . . . . . . . 21 Tetzlaff, Wolfram. Preclinical Approaches to Spinal Cord Repair: Transplantation of Schwann Cells Generated from Skin-Derived Precursors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Curt, Armin. Development of Appropriate Stratification and Outcome Algorithms in Clinical SCI Trials. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Podium Abstracts.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Order: Abstracts are listed in order of appearance per the Interdependence 2012 program. O1-01 - Expectations of Risk, Benefit, and Preclinical Scientific Rigor in Experimental Treatments for Spinal Cord Injury: A Survey of SCI Individuals. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 O1-02 - PTEN Deletion Promotes Regenerative Sprouting in the Aged Rubrospinal Tract. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 O1-03 - Assessment of Cervical Spinal Cord Injury Models: Comparison and Validation Using Extensive Neurobehavioural Assessment and Stem Cell Therapy. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 O1-04 - Objective Spinal fMRI Metrics Distinguish Complete and Incomplete Clinical Grade in Chronic Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 O1-05 - Elevated Circulating Levels of the Pro-Inflammatory Cytokine Macrophage Migration Inhibitory Factor (MIF) in Chronic Spinal Cord Injury (SCI) Patients... . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 2 O1-06 - Semaphorin 5B is Critical to Axonal Guidance in the Chick Spinal Cord. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 O1-07 - Creation of an Anatomic Atlas of Cervical Spine Intradural Anatomy using Fiesta MRI.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 O1-08 - Vegf and Pdgf as an Immunomodulatory Strategy for the Reduction of Secondary Degeneration after a Model Spinal Cord Contusion Injury in Rats.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 O2-01 - Exercise Capacity and Tolerance During Inpatient Spinal Cord Injury Rehabilitation: Preliminary Findings. . . . . . . . . . . . . 27 O2-02 - Improving Muscle Co-Activation in Spinal Cord Injured Individuals Using Body-Weight Supported Treadmill Training. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 O2-03 - Effects of Varying Forward Trunk Inclination During Sitting Pivot Transfers on Upper Limb Loads in Individuals with a Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 O2-04 - Exercise Self-Efficacy Following Discharge from Inpatient Spinal Cord Injury Rehabilitation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 O2-05 - Controlled Nerve Lesioning with Direct Current. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 O2-06 - Antiosteoporotic Effects of Alendronate on Younger Patients with Acute Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . 31 O2-07 - Quantifying Proprioception in the Lower Limbs Using a Robotic Exoskeleton.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 O2-08 - Online Delphi to Identify Targets for Best Practice Implementation and Associated Performance Measures. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 O3-01 - The Brain and Spinal Cord Response to Sensory Stimuli: An fMRI Study. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 O3-02 - Influence of Surgical Delay on Hospitalization Costs and Length of Stay Following a Traumatic Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 O3-03 - Responsiveness of a Clinical Impairment Measure Specific for Traumatic Tetraplegia: A Multi-Centre Assessment of the Grassp Outcome Measure.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 O3-04 - Walking Measures Inform SCI Rehabilitation Practice and Research.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 O3-05 - Classifying Neurological Impairment and Spinal Column Injuries: Does Administrative Coding Accurately Represent Clinical Diagnoses?. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 O3-06 - Rick Hansen Spinal Cord Injury Registry and Ontario Spinal Cord Injury Registry: Relationships Between Respiratory Status and Length-Of-Stay in Acute Care and Rehabilitation.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 O3-07 - Prognostic Value of Multimodal Neurophysiological Evaluation in Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 O3-08 - Outcomes in the Va Sci/D System of Care: Collection, Analysis, Utilization. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 O4-01 - Spinal Cord Injury Model Systems Database: Continuing 40 Years of Progress. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 O4-02 - The Rick Hansen Spinal Cord Injury Registry: An Update.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 O4-03 - Review of Knowledge Translation and Implementation Strategies in Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 O4-04 - Intramuscular Diaphragm Pacing for Respiratory Support in Tetraplegics: Current Worldwide Status in 2010. Why isn’t Available Technology Utilized?. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 O4-05 - A Global Perspective on the Frequency of the Leading Causes of Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 O4-06 - Spinal Cord Injury in the Majority World: Challenges and Opportunities in Providing Standard Care. . . . . . . . . . . . . . . . . . . 41 O4-07 - Addressing Privacy Requirements for the Development of a National Health Registry in Canada. . . . . . . . . . . . . . . . . . . . . 41 O4-08 - The Development of Canadian Best Practice Guidelines for the Prevention and Treatment of Pressure Ulcers in the Spinal Cord Injured Population.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 3 Poster Abstracts.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 Order: Abstracts are listed in order of appearance per the Interdependence 2012 program. P1-01 - Regaining Functionality Following a Spinal Cord Injury (SCI): Central Issues for SCI Consumers. . . . . . . . . . . . . . . . . . . . . . 43 P1-02 - Patient Advocacy as a Force to Advance SCI Research. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 P1-05 - Scoping the Field of Research and Management of Neuropathic Pain After Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . 44 P1-08 - An Inter-Professional Clinical Initiative in an Outpatient Spinal Cord Injury (SCI) Rehabilitation Setting: Pathways to Well-Being Following SCI Community Reintegration Service.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44 P1-09 - The Case for Transvenous Phrenic Nerve Pacing After a High-Level Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 P1-10 - A Kinetic Evaluation of a Novel Forearm Crutch with a Shock Absorption System. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46 P1-11 - Creating the Winning Conditions to Ensure Sustainable Best-Practice Implementation - The Irglm Experience. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 P1-12 - The Effects of Pharmacological Agents on Walking in People with Spinal Cord Injury: A Systematic Review.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 P1-13 - UTI’s and Intermittent Catheterization, What Does the Evidence Say?. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48 P1-14 - The Osteoporosis Guidelines of the Joint Organizations of the German-Speaking Bone Research Societies and their Meaning for Paralyzed Elderly Patients. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49 P1-15 - Evidence Based Management of Depression Following Spinal Cord Injury: A Meta-Analysis.. . . . . . . . . . . . . . . . . . . . . . . . . 49 P1-16 - Using Scoping Review Methodology to Conduct a Canadian Spinal Cord Injury (SCI) Rehabilitation Environmental Scan.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 P1-17 - My Life, My Health Chronic Disease Self-Management Program in Rehabilitation.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 P1-18 - SCIRE 3.0: A Platform for Developing Initiatives to Enhance Practice. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51 P1-19 - Gabapentinoids are Effective in Decreasing Neuropathic Pain Intensity Post SCI: A Meta-Analysis. . . . . . . . . . . . . . . . . . . . 51 P1-20 - Effectiveness of Botulinum Toxin in Treating Neurogenic Detrusor Overactivity Post SCI: A Systematic Review and Meta-Analysis. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 P1-21 - Leveling the Playing Field - Making SCI Primary Care Accessible.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 P1-22 - Factors Influencing Return to Community Living of Persons with SCI and their Family Members : for an Ecosystemic Perspective. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 P1-23 - The Effects of the “Discovering The Power In Me” Program in Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 P2-01 - Icd-10 Coding Accuracy for Spinal Cord Injured Patients. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 P2-02 - Development of an Integrated, Distributed Clinical Research Database for Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . 55 P2-03 - Effects of Seated Double-Poling Ergometer Training on Aerobic and Mechanical Power in Paraplegics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55 P2-04 - Design and Progress of the Swiss Spinal Cord Injury Cohort Study (Swisci). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 P2-05 - Best Practice Implementation in Inpatient Spinal Cord Rehabilitation – The Challenges of a Multi-Unit Site.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 P2-06 - Systematic Review of Economic Studies in Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58 P2-07 - A National Approach to Implementing and Sustaining Evidence-Based Practices for Treatment and Prevention of Secondary Complications for Individuals with Spinal Cord Injuries. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58 4 P2-08 - First Year Anniversary of the Rick Hansen Spinal Cord Registry in Western Quebec: Facts and Figures at a Glance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 P2-09 - Muscle Strength Changes Recorded Using Dynamometry During Robot Assisted Gait Training. . . . . . . . . . . . . . . . . . . . . . . 60 P2-10 - The Development of an Outdoor Experiential Therapy (OET) Cottage Program for Persons with Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60 P2-11 - Evaluating the Effects of an Inter-Professional Therapeutic Cottage Program on Improving Well-Being in Persons with Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61 P2-12 - Cardiovascular Control in the Acute Period after Spinal Cord Injury: A Case Series.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62 P2-13 - Systems Thinking Perspectives in Spinal Cord Injury Research and Practice.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62 P2-14 - Examining Workplace Activity Limitations Among Young Adults Living with Spinal Cord Injuries: A Pilot Study.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 P2-15 - Economics of Traumatic Spinal Cord Injury in Canada. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 P2-16 - Non-Neurological Complication Rate Following Surgical Stabilization of Vertebral Fracture with Neurological Impairment. Does Surgical Timing Matter?. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64 P2-17 - Patient-Centred Care: Using Operations Research Techniques to Improve Care for Persons with Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64 P2-18 - Does Autonomic Dysfunction Play a Role in the Development ff Cardiovascular Disease After Spinal Cord Injury?. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65 P2-19 - Access to Primary Care for Persons with SCI: A Health Service Delivery Study. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66 P2-21 - Use of the Spine Adverse Events Severity (Saves) Instrument for Traumatic Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . 66 P2-22 - Long-Term Follow-Up of Bladder Function in Patients with Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67 P2-23 - Does Bacteriuria Matter in Patients with Neurogenic Lower Urinary Tract Dysfunction?.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67 P2-25 - Self-Reported Physical Activity of Individuals With SCI at Admission and Discharge from Inpatient Rehabilitation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 P3-01 - The Acute Effects of Circulating Cytokines on Peripheral Nerve Function in Humans. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69 P3-02 - Mapping the Interactions of Chronic and Acute Noxious Sensations in the Spinal Cord.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69 P3-03 - Influence of Classical Music on Neural Activity and Pain Response in the Spinal Cord Using Functional Magnetic Resonance Imaging. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70 P3-04 - An In Vivo Experimental Platform for Chronic Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70 P3-05 - Dietary Treatments for Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71 P3-06 - Establishing a Model Spinal Cord Injury in the African Green Monkey for the Preclinical Evaluation of Biodegradable Polymer Scaffolds Seeded with Human Neural Stem Cells. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72 P3-07 - A Model for Bridging the Translational Valley of Death in Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72 P3-08 - Development of a Knowledge Translation Program Among Spinal Cord Injury Patients in Acute Care. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 P3-09 - Critical Appraisal Tools for Preclinical Studies in Spinal Cord Injury Research. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74 P3-10 - Investigating Knowledge Translation Between Biomedical Researchers, Knowledge Facilitators and Wheelchair Users. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74 P3-11 - Practical Steps Towards Knowledge Mobilization in Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76 5 P3-12 - Evaluation Of Diffusion Tensor Magnetic Resonance Imaging to Improve Fiber Tract Assessment in Humans. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77 P3-13 - Early Surgical Decompression for Traumatic Cervical Spinal Cord Injury (SCI): A Cost-Utility Analysis and Feasibility Study.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 P3-14 - Institute for Functional Restoration (IFR).. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 P3-16 - Identifying Quality of Life Outcome Tools for Measuring the Impact of Pressure Ulcers in Persons with Spinal Cord Injury.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79 P3-17 - Spinal Cord Injury Quality of Life Instruments: Do They Measure What They Are Supposed to Measure?.. . . . . . . . . . . . . . 80 P3-18 - On a Roll: Creating a Provincial Action Strategy to Address Quality of Life Issues for People with Spinal Cord Injury. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 P3-19 - Towards Interventions Focusing on Community Living and Quality of Life for Individuals with Spinal Cord Injury: The Com-Qol Team. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81 P3-20 - Effect of Motor Score on Adverse Events and Quality of Life in Patients with Traumatic SCI. . . . . . . . . . . . . . . . . . . . . . . . . . 82 P3-21 - Investigating Life Satisfaction of Community-Dwelling Individuals Living with a Traumatic Spinal Cord Injury in Ontario, Canada – A Pilot Study. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82 P3-22 - Housing for Everyone. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 P3-23 - Translation, Transition, & Transformation - Mental Health for Persons with SCI, Families, and Care-Givers.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 P3-24 - Altering Inflammation After Spinal Cord Injury Using Biomaterials.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84 Author index.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 6 Executive Summaries Order: Summaries are listed in order of appearance per the Interdependence 2012 Program. Only summaries received at the time of printing are included. of treatment has occurred. This has resulted in a lower risk of death from urologic causes during follow up and a better related quality of life. Autonomic Dysfunctions and Sexual Health Following Spinal Cord Injury It is generally accepted that kidney function depends for an important part on lower urinary tract (LUT) function. In the LUT pressure development during bladder filling and during voiding should be low. Proper regular bladder emptying is needed. Continence of urine is important but being continent all the time does not mean functional safe bladder or kidneys. Diagnosis will be done with history, clinical evaluation, including neurological tests of the lumbosacral innervations. Most guidelines advocate the urodynamic testing and simultaneous imaging if possible. Intermittent catheterization and self catheterization have become the treatment of choice. But in some individuals indwelling catheter, suprapubic catheter can be indicated. Bladder relaxing drugs in proper dosage can help keep bladder pressure low. Most frequent complication is urinary tract infection. Regular follow up is important with history, urine and eventually blood analysis, imaging and other test as needed. During urological management the comprehensive complete management should be looked at. Major decisions will be finally made by the patient. Urological management should also involve those who are close to the patient during rehabilitation and when back in the community, implicating education and communication. Andrei Krassioukov, MD, PhD, FRCPC University of British Columbia (Canada) Both men and women commonly suffer sexual dysfunction secondary to spinal cord injury (SCI). SCI disrupts the neurological pathways required for the sexual spinal reflexes, including arousal, orgasm and ejaculation. Sexual consequences of SCI not only significantly alters quality of life, but sexual activity itself can result in life- threatening changes in cardiovascular responses. The cause of these changes is disruption of spinal autonomic circuits vulnerable to trauma of the spinal cord. However, autonomic control of sexual function is one of the least investigated systems in humans, despite the priority of sexuality that has been indicated by persons with SCI themselves. Our data and data from literature suggest that during the sexual activities the systolic arterial blood pressure could be elevated up to 300 mmHg as a result of autonomic dysreflexia (AD). Nearly all episodes of AD occurred in individuals with SCI above the T6 level with the severity increasing with higher lesion levels. Commonly individuals with SCI associated these episodes as new perception of orgasm. We still do not fully appreciate the significance of partial preservation of the descending autonomic pathways and their role in ejaculation predictability and provoked episodes of AD. The likelihood of AD being triggered during sexual activity largely depends on the nature of the stimulation with selfstimulation being less likely to trigger AD than vibrostimulation, and the nature of the injury with higher injury levels resulting in a higher likelihood of AD. Future research needs to characterize exact changes in cardiovascular parameters during sexual activity in SCI patients at home during usual sexual activity in order to develop recommendations for managing AD at home during these activities. Advancements in the Management of Bladder and Male Sexual Function After Spinal Cord Lesion Jean-Jacques Wyndaele, MD Antwerp University Hospital (Belgium) The prevalence of neurologic dysfunction of the lower urinary tract is high when a spinal lesion occurs. The last decades have seen some important evolutions mostly in knowledge and understanding. Also optimization of diagnostics and forms Sexual function is part of the post spinal lesion rehabilitation. Discussion about it should be offered to all spinal cord lesioned individuals and the relatives involved. There are different modalities to permit a proper erection. For fertility, actual methods of sperm retrieval and fertility clinic techniques have made pregnancies possible in many couples. The International Spinal Cord Injury DATA SETS developed by ISCOS-ASIA on different subjects are very helpful to guide diagnosis, treatment and follow up (see relevant web sites ISCOS.org.uk and asia-spinalinjury.org). Urodynamic investigation After Spinal Cord Injury: One-Channel Cystometry vs. Multichannel Urodynamics Mouwang Zhou, MD Peking University 3rd Hospital (China) It is important to identify the type of neurogenic lower urinary tract dysfunction after spinal cord injury (SCI). It could not be predicted by the location of injury and neurological examination. Regular multichannel urodynamic observation should be performed to assess the function of bladder and 7 urethral. Unfortunately multichannel urodynamic system was not a standard equipment in every SCI rehabilitation center in China. In this situation, one channel device with transurethral catheter provide an alternative way. It is easy to get and perform, cheap and applicable. And it also revealed significant contribution in assessing lower urinary tract function, especially in measuring parameters during filling phase. We compared one-channel cystometry with multichannel urodynamics in 35 patients after SCI. The simple one-channel cystometry immediately followed by a regular multichannel urodynamics. It has shown good correlation between these 2 methods for the detection of neurogenic detrusor overactivity. We also found that the autonomic dysreflexia (AD) was not rare in the SCI patient above T6 while used electrocardio and blood pressure monitoring during urodynamic investigation. It is recommended that blood pressure measurement during filling phase in urodynamic observation maybe a proper method to diagnosis potential AD after SCI. and videos on sexual and fertility issues are allowing for better educational dissemination to clients and health care practitioners. Bioengineered Strategies to Promote Repair of the Injured Spinal Cord Michael Fehlings, MD, PhD, FRCSC, FACS Toronto Western Hospital (Canada) This talk will summarize recent work examining promising bioengineered strategies which address key therapeutic targets for spinal cord injury: 1) Bioengineered transcription factors that upregulate VEGF (ZFP-VEGF constructs) 2) Self-assembling peptides (SAPS) to target the glial scar and act as a structural scaphold and Sexual and Fertility Rehabilitation: What’s New and Productive Stacy L. Elliott, MD University of British Columbia (Canada) There is a noticeable improvement in attitude and interest around sexuality after spinal cord injury in the last decade. Specifically, some of the newer medications for erection enhancement are being delivered daily instead of prn use, allowing for more normalcy in function. Vacuum devices are being utilized for penile rehabilitation well as erection enhancement, and may improve the capacity of other medications. Erectile enhancement in men with cauda equina still continues to be a challenge. There are no new vibrators adequate for ejaculation: prototype production of the ICORD/BCIT has halted due to lack of market funding. Viberect, a new vibrator on the market, may only be adequate for erection promotion. Female sexual issues still respond poorly to medication and are addressed more symptomatically, including the use mindfulness techniques, lubricants and vibrators. Neuroplasticity remains the major focus on maximizing sexual potential for both men and women following SCI. Improvement in pelvic floor tone may also assist sexual function and continence in both sexes. Condom use is not favored by men with SCI due to the unreliability of erection in many cases. The use of hormonal birth control methods are utilized more frequently than not, depending on mobility. Furthermore, data are encouraging for men with SCI to pursue lower cost/invasive procedures for fertility prior to higher reproductive technology. Newer data is also accumulating on the risk of hypogonadism in men following SCI and the accelerated health risks for post-menopausal women with SCI. On a positive note, new Clinical Practice Guidelines put out by the PVA on Sexuality, as well as informative books and downloadable manuals 8 3) A polymeric mixture of hyaluronic acid and methyl cellulose (HAMC) to act as a drug delivery system and reduce the inflammatory response to neural injury. The three approaches could be complementary to cell-based strategies and other regenerative techniques Targeting the Extracellular Matrix to Repair Spinal Cord Injury James Fawcett, PhD Cambridge Centre for Brain Repair (United Kingdom) Repair of damage to the nervous system requires axon regeneration, plasticity and cell replacement. The extracellular matrix plays a central role in restricting these processes, mainly through the action of chondroitin sulphate proteoglycans (CSPGs). An important agent in removing this restriction has been the enzyme chondroitinase, which removes glycosaminoglycan (GAG) chains from CSPGs. CSPGs are upregulated in glial scar tissue around injuries to restrict axon regeneration, and digestion of the scar tissue with chondroitinase enhances axon regeneration and sprouting. An unexpected finding has been the role of CPSGs in the restriction of plasticity. This effect is mediated by cartilage-like structures surrounding neurons, known as perineuronal nets (PNNs). Plasticity, one of the main mechanisms for recovery after nervous system injury, is greatly reduced after the critical periods of childhood. This reduction depends on deposition of PNNs around some classes of neurons throughout the CNS. PNNs are particularly prolific in the spinal cord. They contain inhibitory CSPGs, hyaluronan, link protein and tenascin‑R, partly produced by the neurones themselves and partly by surrounding glial cells. Animals lacking PNNs, or after PNN digestion by chondroitinase, possess enhanced levels of plasticity into adulthood. After CNS damage they show greatly increased recovery. However, for recovery of many functions, opening a window of plasticity must be combined with appropriate rehabilitation in order for recovery to occur. Chondroitinase treatment is still effective if given one month after injujry. If given with anti NogoA the combination treatment is more effective than either treatment alone. Dietary Strategies for Acute Spinal Cord Injury Wolfram Tetzlaff, PhD University of British Columbia (Canada) The current guidelines for nutrition after spinal cord injury (SCI) are not based on evidence but rather expert opinions. We studied the effects of dietary strategies in animal models of spinal cord injury. Previously, we discovered that fasting every other day improved functional outcomes after cervical SCI in rats. However, a fasting regimen may be met with little enthusiasm from patients, dietitians and physicians, due to possible weight losses in addition to those seen already caused by paralysis. Hence, we explored the effects of a high-fat, and very low-carbohydrate regimen known as ketogenic diet (KD) which mimics some aspects of fasting (e.g. high blood levels of ketones). KD is effectively used in humans for cases of drug resistant epilepsy. We used a clinically relevant cervical hemi-contusion injury in adult male rats and allowed access to either a standard carbohydrate-based diet, or KD beginning at 4 hours after injury. KD-treated rats showed improved usage and range of movement of the affected forepaw during rearing and grooming behavior. In addition, KD regimen improved grasping success with recovery of wrist and digit movements. Importantly, after returning to a standard carbohydrate-based diet after 12 weeks of KD treatment, the beneficial effects on forelimb function remained stable for at least 6 weeks. No effects on body weight, cholesterol levels or bone morphology/ density were observed. A short term KD regimen enhances functional recovery from SCI in rats and has lasting therapeutic effects without apparent side effects. From a translational perspective, our results mandate the reconsideration of standard clinical practices, which have traditionally promoted high carbohydrate nutritional content in acute SCI patients. We encourage opening further dialogue on this important aspect of patient care in acute SCI, given the limited interventions currently available for this devastating injury. The Cethrinphase I/IIA Trial to Treat Acute Spinal Cord Injury: Update on Results Lisa McKerracher, PhD BioAxone BioSciences Inc. (United States) Cethrin™ is an investigational biologic drug has completed a Phase 2a study in patients with spinal injury (SCI). Cethrin acts on Rho, a signaling protein important in controlling axon regeneration and cell survival after acute SCI. A dose escalation, open-label, clinical study was undertaken to test the safety and tolerability of the drug and neurological status following a single application during surgery following acute SCI. We treated 32 patients with thoracic SCI and 16 patients with cervical SCI at 9 clinical sites in the USA and Canada. Cethrin was safe and well tolerated, with no serious adverse events associated with administration of the drug. Thoracic patients treated with Cethrin showed a positive trend to improvement for both light touch and pin prick scores. Cervical patients treated with Cethrin averaged motor scores of 18.6 across all dose groups; the 3 mg dose appeared most effective, with a 27 point improvement, over double that expected from historical controls. We examined time to recruitment to detect if the positive trends in motor recovery might be explained by early surgery. Surprisingly, we found that patients who had late surgery showed the most interesting trend of motor improvement. We also detected a trend to improved bladder function in the Cethrin treated cervical population. Motor scores were compared in patients who received steroids as part of standard of care with those who did not, and no trends for treatment effects of steroids were evident. The trends we report here are not validated as significant endpoints, but indicate that further study of Cethrin is warranted. Accelerating Progress Through Global Standards: The International Spinal Cord Injury Data Sets Fin Biering-Sørensen, MD, DMSc University of Copenhagen (Denmark) Survival of spinal cord injury (SCI) with a reasonable quality of life has become an expected outcome, and there is an increasing need for data pertaining to SCI. Therefore common International SCI Data Sets should be collected on individuals with SCI to facilitate comparisons regarding injuries, treatments, and outcomes between patients, centers and countries. The International SCI Core Data Set was developed to standardize the collection and reporting of a minimal amount of information necessary to evaluate and compare results of published studies, e.g. including information on the gender and age at the time of injury, the current age, length of time after injury, calendar time frame when the study was conducted, 9 causes of spinal cord lesion, and neurologic status. Data from the Core Data Set are recommended, as a descriptive table in most publications including individuals with SCI. International SCI Basic Data Sets are the minimal number of data elements, which should be collected in daily clinical practice for a particular topic. Therefore the various Basic Data Sets can be the basis for a structured record in centers worldwide caring for individuals with SCI. In addition these Basic SCI Data Set elements should be included in future SCI research for the relevant topics. Today International SCI Basic Data Sets are available regarding Spinal Column Injury, Lower Urinary Tract Function, Urodynamic, Urinary tract imaging, Bowel Function, Female Sexual and Reproductive Function, Male Sexual Function, Cardiovascular Function, Pulmonary Function, Endocrine and Metabolic Function, Skin and Thermoregulation Function, Muscleskeletal Function, Pain, and Quality of Life. International SCI Extended Data Sets are more detailed data sets, which may be recommended for specific research studies within the particular area. All data sets are available at the web sites of ISCoS (www. iscos.org.uk). International SCI Data Sets development. Working groups are established in cooperation with relevant international societies and organizations. For each data set a syllabus with data collection form and instructions on how to collect data are developed. Organizations and societies within the fields of SCI, neurosurgery, orthopaedic surgery, rehabilitation and others are being invited to review the International SCI Data Set. Anybody else is also welcome to join the review process. Process for approval of International SCI Data Sets. An iterative process for approval of the data sets has been established, including review by ISCoS Scientific Committee, ASIA Board, relevant and interested (International) Organizations and Societies and persons. In addition the data sets are on the web sites of ISCoS and ASIA for at least one month.Variable names and Data base structure. For the data elements in each International SCI Data Set are consistent variable names and a common database structure developed in cooperation with the National Institute of Neurological Disorders and Stroke (NINDS), the National Institutes of Health (NIH), embarked on a Common Data Element (CDE) Project. The database structure allows data to be stored in a uniform way in databases to promote sharing data from different studies. Implementation of Best Practices: A Multi-Layered Global Challenge Keith C. Hayes, PhD University of Western Ontario (Canada) The tortuous journey from discovery to implementation of best practices encounters mountains, chasms and different forms of hostile environments; these challenges are especially daunting when the destination is global. With no clear atlas to guide the journey many travellers fall by the wayside. Fortunately the past decade has witnessed a proliferation of traveller’s aids to help navigate the path. In this presentation we examine the models, tools, infrastructures and resources that facilitate the translation of robust new evidence into clinical practice. The road travelled by investigator-driven clinical innovation parallels that taken by for-profit commercial research and development (biotech, medical devices and pharma developments) with slight variants in the filters that are applied with respect to good manufacturing process, risk management, professional uptake, health technology assessment, regulatory approval, market considerations, reimbursement and investment opportunity. Innovation in both domains impact practice and outcomes and are often interdependent. Travellers along both paths will benefit from the emerging science of implementation and initiatives that are underway to encourage globalization of best practices. The SCI Community Survey: Toward a Better Understanding of Support Services That Enhance Community Living Luc Noreau, PhD Universite Laval (Canada) Introduction and objective: The SCI Community Survey is the largest study of its kind. Its aim is to confirm the most important SCI-specific needs of Canadians with SCI and their relationship with the access/barriers to service utilization and major outcomes impacting community living. Methods: The study design process led to the identification of 13 needs for services (e.g., housing, transportation, attendant services) favoring community living and a series of major outcomes (secondary complications, participation, employment, quality of life). Participants were recruited through a nationwide consumer awareness program with the partnership of The Canadian Paraplegic Association and several rehabilitation facilities. Respondents accessed the survey in a web-based format or via telephone interview. Preliminary Results: Initial results with more that 900 participants with traumatic SCI indicated that needs for services are highly prevalent in the SCI population (> 85%) for dimensions like equipment and devices, health care, 10 accessible housing, transportation. While a significant proportion of participants (60-70%) considered that, overall, their health care needs were largely met, this proportion decreased when secondary complications (often untreated) negatively impacted daily activities. Results on social participation suggest that a significant proportion of people with SCI cannot participate at all in specific life domains in which they would like to be involved. activities undertaken by SCI Action Canada with an emphasis on strategies used to maximize the reach and implementation of our best practices both nationally and internationally. Recommendations will be presented regarding the use of the community-university partnership approach to develop, evaluate, and implement best practices. Conclusion: When completely, the SCI Community Survey will inform stakeholders about the living situation of people with SCI and their needs for services from the Canadian social service system. For example, we know that the Canadian health care system must address the issue of untreated SCs that significantly impact daily living and must consider strategies to increase social participation of those who cannot participate. Such results from the SCI Community Survey are preliminary steps before establishing and prioritizing best practices for an enhanced community living after SCI. Communicate, Collaborate, Cure... Networking Down Under Support: The Rick Hansen Institute and The Ontario Neurotrauma Foundation. Acknowledgement: The authors gratefully acknowledge the initial support of the Community Integration Practice Network Team (K. Boschen, G. Jacquemin, K. Martin Ginis, M.A. McColl, B. Miller, D. Wolfe, T. Clarke, B Adair) and the invaluable commitment of the survey participants Best Practices Implementation through Community-University Partnerships Kathleen A. Martin Ginis, PhD McMaster University (Canada) SCI Action Canada (www.sciactioncanada.ca) is an example of a community-university partnership approach to developing and implementing best practices. It is an alliance of 30 community-based organizations and university-based researchers working together to increase physical activity participation among people living with SCI. The alliance is underpinned by a commitment to the rigorous development and testing of physical activity-enhancing resources and interventions, and the translation of those innovations into products and services for implementation within the SCI community. Some examples of SCI Action Canada’s research and knowledge translation activities include: development and the launch of the first ever evidence-based physical activity guidelines for adults with SCI; development and the launch of an evidence-based, SCI-specific physical activity Toolkit; translation of two randomized controlled trials into a nation-wide, telephone-based physical activity counseling service for people with SCI; development and evaluation of evidence-based, print and video physical activity resources for persons with SCI. This presentation will provide an overview of Stephanie Williams, PhD Spinal Cord Injury Network (Australia) The Spinal Cord Injury Network (SCI-N) was established in 2008 to unite scientists, clinicians, the community and other key stakeholders across Australia and New Zealand (ANZ) around promoting recovery from spinal cord injury (SCI). As well as providing a suite of communication and education initiatives that bring our stakeholders together, a key focus of the Network is to facilitate research development and multi-centre clinical trials. A recent survey conducted by SCI-N reviewed barriers and facilitators for conducting clinical trials into SCI in NSW. Fifty-eight percent of respondents ranked funding as the most important barrier to conducting clinical trials. The second most common identified barrier was lack of staff, third was lack of time, and fourth was recruitment. All but one of the respondents said they were planning to build on their existing research. Patient enrollment is the most time-consuming aspect of the clinical trial process. The leading cause of missed clinical trial deadlines is patient recruitment, taking up to 30 percent of the clinical timeline. Improving patient recruitment rates offers researchers one of the biggest opportunities to accelerate the pace of clinical trials. Approximately one person a day sustains a SCI in ANZ with an estimated prevalence of more than 12,000 individuals. Most participants in clinical trials are recruited through the nine spinal units based in capital cities. Participant recruitment also occurs via specialized databases, State-based databases or through advertising. To overcome recruitment barriers, studies need to be conducted at multiple centres across ANZ. There are several examples of multi-centre clinical trials currently underway, which include SCIPA (Spinal Cord Injury Physical Activity study), COSAQ (CPAP for Obstructive Sleep Apnea in Quadriplegia) and AusCAN (risk assessment for sitting acquired pressure ulcers).To further facilitate the conduct of clinical trials, SCI-N has formed a Clinical Trials Committee with bi-national representation that meets quarterly. Its aims include: • To facilitate collaboration and support multi-centre SCI clinical trials in ANZ; • Register local researchers/research groups and areas of expertise / interest, to assist planning of clinical trials, 11 and provide advice and information to researchers on SCI clinical trials and to potential subjects considering participation • Promote the development and use of appropriate standardized clinical trial protocols, and internationally recognized and evidence-based data collection tools and assessment measures. • In support of this last aim, in 2011 SCI-N commissioned Professor John McNeil’s team at Monash University to provide advice on how to build on the existing infrastructure of the Australian SCI Registry (ASCIR) and redevelop the ASCIR as a data platform capable of supporting issues relevant to management, outcomes and research in the future. The update will align with a partnership grant on access to care in NSW and VIC called “Right care, right time, right place” led by Professor James Middleton, Director of the NSW State SCI Service. The study will examine key processes along the early care pathway from scene of injury to definitive care, and lay the foundation for future trials involving early interventions. The above summarizes activities SCI-N has undertaken to assist in optimizing the conduct of clinical trials in ANZ. SCI-N would fully support the use of this infrastructure to coordinate with other networks on an international level as part of a global clinical trials network. Building and Maintaining a Multispecialist SCI Center James S. Harrop, MD Thomas Jefferson University (United States) Optimal SCI patient care requires a multidisciplinary care of the patient. The aim of this talk is to discuss the evolution of this concept to present treatment facilities. Jefferson Medical College is one of the oldest national model SCI centers. It has continually changed and evolved in the care of patients through a direct physician interaction. The talk with review our system and collaborations between the Orthopedic, Neurological and Trauma surgeons as well as Physiatrists ChinaSCINet Clinical Trials Wise Young, MD, PhD Rutgers University (United States) Three decades ago, most scientists believed that the spinal cord cannot regenerate. In the early 1980’s, David & Aguayo from Montreal reported that spinal cord axons regenerate when placed into peripheral nerve. This stimulated an intense search for axon growth inhibitors in spinal cord. Several inhibitors were identified, including Nogo and chondroitin- 12 6-sulfate proteoglycan (CSPG). In the 1990’s, many investigators reported that blockade of Nogo or its receptors, and use of chondroitinase to break down CSPG, will stimulate axon regeneration and functional recovery in animals. The past decade, however, yielded conflicting results. Knocking out Nogo-A (and similar molecules) did not promote spinal cord regeneration. Likewise, chondroitinase was not always effective in spinal cord contusion models. Combinations of neurotrophins or cAMP stimulate axon growth and improve functional recovery in animal models despite continued presence of Nogo and CSPG in spinal cord. Liu, et al. recently reported that blocking the gene PTEN in mouse motor cortex allows massive regeneration of corticospinal axons, suggesting that certain genes constrain corticospinal axon growth. Together, these studies suggest that spinal axons will regenerate if provided growth factor support or blockade of PTEN, despite continued presence of Nogo or CSPG in the spinal cord. In 2004, Wu, et al. at HKU reported that lithium and chondroitinase markedly enhanced regeneration in hemisected rat spinal cords. Su, et al. found that lithium stimulates neural stem cells to proliferate and to produce neurotrophins. In 2008, Gill, et al. reported that lithium alone stimulates axonal growth in vitro and in the spinal cord, promoting functional recovery. We found that lithium stimulates umbilical cord blood mononuclear cells (UCBMC) to proliferate and to produce the neurotrophins NGF, NT3, and GDNF known to stimulate long tract growth in spinal cord. Many groups reported that UCMBC not only survive for weeks in mouse, rat, and dog spinal cords but improve neurological recovery after spinal cord injury (SCI). We proposed that lithium will enhance beneficial effects of UCBMC in SCI. To assess the effects of UCBMC and lithium on chronic SCI, we are doing the following clinical trials. The first (CN101) showed that lithium can be safely given to people with chronic SCI. The second (CN102A) showed that lithium does not improve neurological recovery but reduces neuropathic pain in chronic SCI. The third (CN102B) compares safety and efficacy of increasing UCMBC doses (4, 8, and 16 µliter of 100,000 UCBMC/µliter), UCBMC with methylprednisolone (MP) and a 6-week course of lithium. To date, we have transplanted UCBMC into 28 subjects with chronic SCI in Hong Kong and China. The treatment appears to be safe. Twenty subjects will have received 3 months of intensive locomotor training. The trial will ascertain whether UCBMC + lithium is safe and improves function. If so, we will initiate multicenter phase 3 trials in China, USA, Norway, and India to assess safety and efficacy of UCBMC plus lithium therapy of chronic SCI. A total of 600 subjects will be tested in this trial starting 2013. Latest Advances in Evaluation of Autonomic Dysfunctions Following Spinal Cord Injury Andrei Krassioukov, MD, PhD, FRCPC University of British Columbia (Canada) It is well known that autonomic dysfunctions, including abnormal cardiovascular control, are common consequences of spinal cord injury (SCI) in humans. However, the International Standards for Neurologic Assessment, commonly referred to as the American Spinal Injury Association (ASIA) neurological examination, only evaluates motor and sensory functions following SCI. In order to improve the evaluation of autonomic function in individuals with SCI, and in the future to assess the effects of therapeutic interventions, ASIA and the International Spinal Cord Society (ISCoS) established a committee to develop a set of definitions and classifications for disorders of autonomic function in SCI. Four major areas were identified: general autonomic dysfunction, bowel, bladder and sexual dysfunctions. For each area, a comprehensive set of definitions was also identified. It is recommended that these dysfunctions following SCI be assessed and documented by clinicians. For example, among general autonomic dysfunctions the recognition and assessment of the following conditions should be performed: level of arterial blood pressure, presence of orthostatic hypotension, autonomic dysreflexia, arrhythmias, temperature dysregulation, sweating dysfunctions and broncho-pulmonary dysfunctions. Members of the committee propose that in the future, in addition to already established motor and sensory assessment standards, the assessment of autonomic functions be a part of clinical evaluation of individuals with SCI. Autonomic standards were recently translated into Chinese and have already been introduced into practice at numerous centres around the world. Finally, our clinical practice could also benefit from use of recently published series of SCI data sets focused on various aspects of autonomic functions. The Presentation and Consequences of Decentralized Autonomic Cardiovascular Control in Persons with SCI Jill M. Wecht, EdD James J Peters VA Medical Center (United States) Spinal cord injury (SCI) results in motor and sensory impairments which may be classified by the American Spinal Injury Association Impairment Scale (AIS). SCI also adversely affects autonomic nervous system (ANS) function; however the AIS classification does not consider ANS dysfunction. Notwithstanding the absence of an accurate measurement tool for ANS dysfunction, it is appreciated that autonomic regulation of the cardiovascular system is altered following SCI and the degree of impairment may relate to AIS. In general, persons with tetraplegia present with low resting heart rate (≤60 bpm) and blood pressure (≤90/60), and orthostatic hypotension (OH), which may limit rehabilitation, independence and quality of life. In fact, although many individuals with tetraplegia remain asymptomatic, we have documented significant deficits in memory and attention processing speed in hypotensive individuals with SCI compared to a normotensive SCI group. Evidence suggests a possible association between chronic hypotension and cerebral hypoperfusion which relate to poor cognitive test performance, and we have preliminary evidence that this may be the case in persons with SCI. Level of SCI may relate to ANS dysfunction and the model of paraplegia highlights this association. Individuals with paraplegia in the upper thoracic cord (T1-T6) often present with hypotension, whereas individuals with low paraplegia (T7 and below) are generally normotensive. Interestingly however, regardless of the level of paraplegia, we and others have reported increased resting heart rate (≥ 84 bpm) and arterial stiffness in these individuals, which may have a deleterious effect on cognitive function. There is evidence of an association between increased arterial stiffness and accelerated cognitive decline and we have preliminary evidence that the proportion of mild to moderate cognitive impairment is increased in individuals with paraplegia. This presentation will review relevant literature and discuss findings on the impact of decentralized cardiovascular autonomic control in persons with SCI. The Influence of Injury to Autonomic Pathways on Cardiovascular Disease Risk After Spinal Cord Injury Victoria Claydon, PhD Simon Fraser University (Canada) The leading cause of morbidity and mortality in individuals with spinal cord injury (SCI) is cardiovascular disease. The mechanisms underlying this increase in risk are unclear. Leading a sedentary lifestyle after SCI has been proposed to be the main contributing factor. However, injury to cardiovascular autonomic pathways may also play an important role in the predisposition to cardiovascular disease after SCI. Individuals with high level autonomically complete SCI have impaired cardiovascular reflex control, with an increased susceptibility to orthostatic hypotension (profound falls in blood pressure when upright) and to autonomic dysreflexia (marked hypertensive episodes following afferent stimuli below the lesion level). This is compounded by impaired cerebral autoregulatory responses that minimise the ability of the cerebral circulation to buffer these marked changes in blood pressure. Individuals with autonomically complete lesions also have abnormal cardiac electrical activity, evidenced by 13 electrocardiographic characteristics that are associated with an increased risk of cardiac arrhythmia. This may explain why cardiac arrhythmia are also common after SCI, particularly during episodes of autonomic dysreflexia. Glucose tolerance and insulin sensitivity are impaired only in individuals with autonomically complete SCI. The severity of impairment in glucose tolerance is positively correlated with the severity of autonomic injury. However, abnormal lipid profiles are evident in both individuals with autonomically complete, and incomplete, lesions. These findings support the need to target treatment towards autonomic dysfunction after SCI, in addition to lifestyle modification, in order to reduce morbidity and mortality due to cardiovascular disease. This work was supported by the Heart and Stroke Foundation of Canada, Christopher and Dana Reeve Foundation, and Simon Fraser University. Metabolic and Endocrine Disorders in Individuals with Chronic Spinal Cord Injury: Predisposition to Cardiovascular Disease William A. Bauman, MD James J Peters VA Medical Center (United States) Persons with chronic spinal cord injury (SCI) have an increased prevalence of disorders of carbohydrate and lipid metabolism. Diabetes mellitus and impaired glucose tolerance are more prevalent in persons with chronic SCI than in able-bodied individuals. Persons with higher cord lesions are generally more insulin resistant than those with lower cord lesions. Depressed serum HDL cholesterol levels in persons with SCI have been demonstrated, and those with the greatest neurological impairment tend to have the lowest levels. Extreme inactivity and unfavorable changes in body composition (i.e., loss of lean body mass and gain of fat mass) most likely play a major role in these metabolic dysfunctions. An inverse relationship has been shown between serum high density lipoprotein (HDL) cholesterol levels and abdominal circumference, and a direct relationship has been observed between measures of abdominal adiposity and triglyceride levels and small, dense low density lipoprotein (LDL) cholesterol levels. One contributing factor to the adverse changes in body composition in those with SCI may be the unfavorable endocrine milieu, with a reduction of anabolic hormones. Serum growth hormone is reduced to provocative stimulation, and insulin-like growth factor is depressed in younger individuals with SCI. Serum testosterone levels are also lower by decade of life in those with SCI than in the able-bodied, and testosterone levels also appears to decrease with longer duration of injury. In those with SCI and testosterone deficiency, testosterone replacement therapy 14 (TRT) has been demonstrated to improve body composition and increase resting energy expenditure, with other potential beneficial effects or TRT yet to be shown. Alterations in serum catecholamines in the general population influence carbohydrate tolerance and lipid metabolism. Thus, autonomic dysreflexia in SCI may be speculated to be associated with insulin resistance and carbohydrate intolerance, whereas depressed basal levels of norepinephrine in those with higher cord lesions may contribute to reduced serum HDL-cholesterol values with associated increased cardiovascular risk. Persons with long-standing SCI have been reported to have increased conventional and emerging risk factors for coronary heart disease (CHD), and they appear to have premature CHD. Niaspan has been demonstrated to safely and effectively raise serum HDL cholesterol levels in a cohort of individuals with SCI. The Challenge of Deciding What to Translate Brian Kwon, MD, PhD, FRCSC University of British Columbia (Canada) The need to establish effective treatments for spinal cord injury has led to the development of many therapeutic strategies over the past 30 years. A handful have been evaluated in human trials and many more are emerging from scientific laboratories and vying for clinical translation. History has revealed, however, that once promising SCI experimental treatments reach the point of translation into human evaluation, their passage through clinical trials is exceedingly challenging. With a relatively low annual incidence of traumatic SCI (compared to other acute neurologic conditions such as stroke or traumatic brain injury), patient recruitment into acute SCI trials can be an agonizingly slow process. And yet, large numbers of patients are typically needed to demonstrate neurologic efficacy in such trials, as spontaneous neurological recovery can occur with substantial variability. The sheer enormity of this process (both in terms of time and money) compels the scientific community to carefully decide which of the many experimental treatments available is to be advanced into human trials. Clearly, the decision to proceed with the clinical translation of experimental treatments is not one to be taken lightly. Despite this, no objective method exists for characterizing the extent to which a particular therapy for spinal cord injury has been scientifically investigated and evaluated for its readiness for translation. The stroke field, having suffered great frustration in the clinical evaluation of neuroprotective treatments that appeared “promising” in animal studies has generated guidelines to direct the preclinical development of such interventions. Developing analogous guidelines in spinal cord injury would seemingly be quite valuable, not only to provide some direction about the testing of potential SCI therapies, and to identify important gaps in the scientific validation and preclinical refinement/ optimization of specific treatments. Preclinical Studies Provide Limited Prediction of Safety and Efficacy in Human SCI Trials NACTN is a consortium of nine Clinical Centers composed of neurosurgery department faculty and staff caring for spinal cord injured patients at university-affiliated hospitals, a Data Management Center and a Pharmacological Center. Armin Curt, MD, FRCPC Balgrist University Hospital (Switzerland) As NACTN developed it addressed the requirements of conducting trials of therapy in SCI: The translation of preclinical knowledge into the therapeutic application in humans is inherently challenged by many unpredictable interactions and effects. Safety issues reside but are not limited to toxicological effects, an area where pharmacology has rather well established pathways to estimate adverse events (like the therapeutic index defined as the LD /ED50 (LD=letal dose; ED=effective dose)). The latter are 50 related to organ specific or systemic effects while reference values (i.e. levels of confidence) can be employed from various established animal models. However safety aspects related to the mode of application (like surgical procedures) are less established and common landmarks of safety are not yet well understood. Measures of efficacy as applied in human studies are even less related or predictable based on outcome measures gained in animal studies (like the BBB score in rats). There are no established relations between observed changes of (sensori-)motor functions in animals (like ambulation or upper limb function) to potential effects in humans (true not only for rodents but also non-human primates). This is even more complicated when the potential magnitude of improvement (beneficial expectation) needs to be balanced against safety concerns (risk of adverse events) to consider the initiation of a clinical trial. Nevertheless these challenges don’t argue per se against the initiation of clinical trials but ask for the introduction of rigorous trial protocols that are positioned to discern both subtle aspects of safety and efficacy. The obvious challenges in translational research can be only overcome by a consorted interaction of basic and clinical research with the application of innovative trial protocols that are beyond rather basic outcome measures (like ASIA scores). Organizational, Regulatory and Financial Barriers to Conducting Clinical Trials in SCI Robert G. Grossman, MD The Methodist Hospital (United States) Promising research developments have not been brought to phase 3 clinical trials that have the design and statistical power to demonstrate efficacy because of the formidable organizational, regulatory and financial barriers that must be overcome to conduct such trials. The North American Clinical Trials Network (NACTN) for Treatment of Spinal Cord Injury was created with the support of the Christopher Reeve Foundation with the goal of overcoming these barriers. 1. Organization of a multicenter network of hospitals capable of enrolling a sufficient number of SCI patients for conducting trials. Establishing governance policies, committees and a system of communications between centers. 2. Creating a Data Management Center and a database of the natural history of recovery after SCI, from the time of injury through the stages of recovery as a prior control group for evaluating the efficacy of new therapies. 3. Creating a database of the incidence and severity of medical and surgical complications that occur during treatment after SCI as a prior control group for evaluating the safety of new therapies. 4. Developing sensitive, quantitative measures of motor, sensory and autonomic outcomes. 5. Developing standards to evaluate the suitability of translating new pharmacological and cell based basic discoveries to clinical trials. 6. Developing the designs and writing the protocols for clinical trials of a new therapy. 7. Developing a pharmacological center with the capability of carrying out pharmacokinetic and pharmacodynamic studies of therapeutic drugs. The steps that NACTN has taken to address the requirements of conducting clinical trials of new therapies in SCI will be presented. Regulatory Considerations to Initiate an Invasive Experimental Treatment for Spinal Cord Injury James D. Guest The Miami Project to Cure Paralysis (United States) The key issues related to gaining regulatory approval to transplant an autologous cellular product into the spinal cord will be reviewed based on recent experience with Schwann cells. It may be beneficial to understand these concepts during preclinical testing and proof of principle experimentation. In preclinical studies the actual human cell product should be used and prepared to near cGMP standards. Since there is a strong emphasis on safety and toxicology the assessment of tissues and outcomes in the pivotal data set must be very 15 through and well documented. For cell therapy key issues related to the cell product testing in animals are cell identity, product stability, product potency, post-implant cell survival and evidence of cell function. Examination of the entire neural axis is needed which is challenging in large animal models. Autologous preparations are especially challenging given that each is derived from a unique donor but offer the important advantage of reduced probability of immune rejection. The Importance of Innovation and Collaboration in Developing New Treatments for Spinal Cord Injury Lisa McKerracher, PhD BioAxone BioSciences Inc. (United States) Translational neuroscience and CNS clinical trials present unique challenges to drug development companies. BioAxone BioSciences’s CEO Lisa McKerracher led bench to bedside clinical development for Cethrin, a drug in Phase 2b development for acute spinal cord injury. Dr. McKerracher will provide insight to successes and challenges in translational neuroscience research and early clinical development. She will discuss translational preclinical success factors, and lessons learned from a biotechnology company perspective. She will discuss the challenge of keeping clinical costs down in the face of a stringent regulatory environment. Her presentation will touch on the recruitment success, training considerations, and how partnerships can help leverage resources. Clinical Translation of Absorbable Biopolymers and Hydrogels for Acute Spinal Cord Injury Edward D Wirth III, MD, PhD InVivo Therapeutics Inc. (United States) InVivo Therapeutics Corporation was founded in 2005 with a core mission to develop and commercialize new technologies for the treatment of spinal cord injuries. Our most advanced product is an absorbable biopolymer scaffold that is designed for implantation into an acute spinal cord lesion. This technology was developed through a collaborative effort between the Massachusetts Institute of Technology’s Langer labs and clinician-scientists at Harvard Medical School. Preclinical safety and efficacy of the scaffold alone or seeded with either neural stem cells or growth factors was evaluated in both rodent and non-human primate models of acute spinal cord injury (SCI). These studies showed that animals receiving scaffolds exhibited a greater degree of locomotor recovery than control animals. In addition, 16 no scaffold-related adverse effects were observed in any animal. Based on these data, an Investigational Device Exemption (IDE) was filed with the FDA in 2011 to begin a pilot clinical study of the scaffold in patients with acute SCI. Our second product platform is a self-assembling injectable hydrogel for the local, controlled release of methylprednisolone (MP). Intravenous administration of MP has demonstrated therapeutic potential for acute SCI, but has significant side effects including: increased risk of death due to infection, delayed wound healing, pneumonia and sepsis. Hydrogel with MP can be injected directly into the spinal cord lesion and is designed to counteract the inflammatory environment in the acutely injured spinal cord. Limiting release of MP to within the spinal cord should avoid the side effects associated with systemic administration of high-dose steroids. Initial preclinical testing showed that administration of hydrogel with MP led to greater locomotor recovery versus controls in an acute non-human primate SCI model. Additional rodent and non-human primate studies are being conducted to further evaluate the therapeutic potential of this technology for acute SCI. Commercialization of SCI Research Kenneth Galbraith Ventures West Capital Ltd. (Canada) In order to ensure the effective commercialization of SCI research, substantial investment will be required by the private sector to fund promising SCI research projects and ensure that the results of such research will be made broadly available to patients and consumers. Such investment will only be provided by the private sector if the environment provides a predictable path to regulatory approval and market for products and a reasonable return on such investment that is consistent with the high level of risk and complexity associated with all medical research. A close working relationship between researchers, industry, regulators, government and payors on a global basis will also be necessary in the area of SCI research. A summary of the risks and opportunities for the commercialization of SCI research will be discussed from the viewpoint of a venture capitalist. Achievements and Challenges in the Development of Human Embryonic Stem Cell Based Therapies Jane S Lebkowski, PhD Geron Corporation (United States) Human Embryonic Stem Cells (hESCs) can proliferate indefinitely yet, upon appropriate cues, differentiate into all somatic cell lineages. These two properties of hESCs enable the development of hESC-derived therapeutic cell populations which can be batch manufactured in central manufacturing facilities, cryopreserved, and distributed for “on demand” use. Protocols have been developed to differentiate hESCs into neural, cardiomyocyte, hepatocyte, islet, osteoblast, chondrocyte, and hematopoietic cell populations which are functional in either in vitro or in vivo animal models of human disease. For example, hESCs have been differentiated into oligodendrocyte progenitors that upon transplantation into animals with spinal cord injuries can remyelinate denuded axons, induce axonal sprouting, and improve locomotor activity. Extensive preclinical studies have been completed to examine the activity, biodistribution, dosing, delivery, and potential toxicity and tumorigenicity of the oligodendrocyte progenitors. The safety of these and other human embryonic stem cell based therapies is now being tested in the clinic in subjects with complete spinal cord injuries and aged related macular degeneration. The Acceleration of Technology in the 21st Century: the Impact on Healthcare and Medicine Ray Kurzweil Kurzweil Technologies (United States) Up until recently, health and medicine was basically a hit or miss affair. We would discover interventions such as drugs that had benefits but also many side effects. Until recently, we did not have the means to actually design interventions on computers. All of that has now changed. We now have the information code of the genome and are making exponential gains in modeling and simulating the information processes they give rise to. We also have new tools, also just a few years old, that allow us to actually reprogram our biology in the same way that we reprogram our computers. RNA interference, for example, can turn genes off that promote disease and aging. New forms of gene therapy, especially in vitro models that do not trigger the immune system, have the ability to add new genes. Stem cell therapies, including the recently developed method to create “induced pluripotent cells” (IPCs) by adding four genes to your own skin cells to create the equivalent of an embryonic stem cell but without use of an embryo, are being developed to rejuvenate organs and even grow then from scratch. There are now hundreds of drugs and processes in the pipeline using these methods to modify the course of obesity, heart disease, cancer, and other diseases. Health and medicine is now an information technology and is subject to the “law of accelerating returns,” which is a doubling of capability (for the same cost) each year. As a result, technologies to literally reprogram the “software” that underlie human biology will be a thousand times more powerful than they are today in a decade, and a million times more powerful in two decades. Neuroprostheses and Telesupervised Exercise to Improve Hand Function: Benefits and Limitations Arthur Prochazka, PhD University of Alberta (Canada) Although electrical stimulation is widely used to strengthen muscles, only a small minority of people with SCI use neuroprostheses to augment hand function in activities of daily life. Surface stimulators are able to activate two or three groups of muscles, to restore hand grasp and release. Though this is limited when compared with dexterous hand movements, nonetheless it can sometimes make an important difference to independence. The only commercially available hand stimulator is suitable for use in the clinic, but its design does not lend itself to use in daily life. I will discuss the HandStim, a wristlet we have developed that fills this gap. Implanted neuroprostheses can target more muscles. I will discuss three neuroprosthetic approaches, the Freehand system, the Stimrouter system and intraspinal microstimulation. Exercise therapy plays an important role in maximizing residual function. Devices have emerged over the last decade that encourage exercise in a structured and entertaining way. Cost is an important factor. I will review and compare robotic and passive exercise devices, with a focus on our experience and future plans of in-home tele-supervised exercise with the ReJoyce computer-gaming device, now in use in several countries. Supported by Alberta Innovates Health Solutions and the Canadian Institutes of Health Research Strategies for Neuromuscular Recovery after Spinal Cord Injury Susan Harkema, PhD University of Louisville (United States) Studies in animals and humans have shown that the functionally isolated human spinal cord maintains specific properties recognized to generate locomotion in other species. These concepts now have been translated into the clinic by the Christopher and Dana Reeve NeuroRecovery Network of seven rehabilitation centers that provide standardized Locomotor Training to individuals with chronic incomplete spinal cord injury. 17 In seven outpatient rehabilitation centers from the Christopher and Dana Reeve Foundation NeuroRecovery Network (NRN), 206 individuals ranging from 0.9 to 26 years post injury were assessed during intensive Locomotor Training, including step training using body weight support and manual facilitation on a treadmill followed by overground assessment and community integration. While significant improvement from enrollment to final evaluation was observed in balance and walking measures for AIS C and AIS D patients, the magnitude of improvement differed significantly between AIS groups for all measures. These results indicate that rehabilitation that provides intensive activity-based therapy can result in functional improvements in individuals with chronic incomplete SCI even years after injury. Institute for Functional Restoration, a New Model for Deployment In another study we hypothesized the human spinal locomotor circuitry has sufficient automaticity potential to generate postural control and rhythmic, coordinated weight bearing stepping and that we can recruit this locomotor and postural circuitry with a tonic epidural stimulation of selected lumbosacral segments. We implanted a 23 years old individual and 3.4 years post injury at the time of surgery. He was clinically assessed as an ASIA B, i.e., some sensory, but no motor function below the lesion (C7). We implanted a 5-6-5 electrode array epidurally spanning L2-S1 spinal cord segments and a neurostimulator (Medtronic) capable of stimulating any combination of the 16 electrodes in the array at intensities up to 10.5V and with frequencies ranging from 2-50 Hz. While sitting, without epidural stimulation, we observed minimal EMG activity in all leg muscles. While standing in a supportive system without stimulation and with assistance provided at both knee joints by a trainer, little or no observable EMG activity occurred in the leg muscles. With epidural stimulation the transition from sitting to standing was accompanied by an increase in the EMG amplitude by orders of magnitude beyond that observed in the sitting position. In addition, after several months of training he was able to voluntarily move his legs in the presence of epidural stimulation. These results demonstrate the interaction between sensory and epidural regulation of locomotor circuitry. The results also show that a physiological state can be achieved with epidural stimulation so that the sensory input can effectively control the locomotor circuitry to stand and to step. In many cases, clinically important technologies remain in the limbo of “research” because they lack the financial model demanded for commercialization. Dr. Hunter Peckham, of Case Western Reserve University, has spent the past 30 years leading a team of investigators to develop and demonstrate feasibility in clinical trials, implantable devices that restore function to those with neurological diseases like SCI. After waiting for a corporate strategy to succeed, he decided that in the case of smaller markets, like this one, perhaps a new model would be needed to transition the research into a fully deployed and approved product. To that end, The Institute for Functional Restoration (IFR) was created within Case Western Reverse University (Case) to fulfill the mission of enabling the clinical deployment of new treatments to orphan populations like spinal cord injury (SCI) and stroke in a sustainable manner. Supported by National Institute of Health and Christopher and Dana Reeve Foundation. Persons with spinal cord injury (SCI) at all levels of injury may benefit from advances in technology. Robotic exoskeletons are a relatively new intervention to allow the wheelchair dependent individuals to enhance the upright position with the ultimate goal of community. The ekos (Ekso Bionics) has completed trials in SCI with the use of assistive devices. Clinical findings of this trial will be presented, as well as a discussion of recent advances made from professionals and users (study subjects input), and goals for future advances. Lastly, technology based updates for the wheelchair user will be presented and its role in the rehabilitation of persons with SCI. 18 P. Hunter Peckham, PhD Case Western Reserve University (United States) Making a real difference in the functional level and quality of life for those with spinal cord injury (SCI) is a goal for countless groups and individuals throughout the world. Billions of dollars in funding has been spent over the past decade on research with the intention of impacting those with SCI, yet the options and innovations available today are strikingly similar to those available a decade before. Why are we not seeing more come from the innovation pipeline into full clinical deployment? Structured as a non-profit, the IFR takes proven feasible research interventions, like those in the Cleveland FES Center, through regulatory approval and production. A key mandate of the IFR mission to ensure a long-term access to the technology and support for those implanted. This presentation will explore the strategy of the IFR model, assumptions made, products planned and status to date. Technological Advances in SCI Steven Kirshblum, MD Kessler Institute for Rehabilitation (United States) Walking with an Exoskeleton for Persons with Paraplegia Ann M. Spungen, EdD James J Peters VA Medical Center (United States) Persons with spinal cord injury (SCI) who are wheelchairdependent are at increased risk for several secondary medical consequences of paralysis and immobilization including: osteoporosis, muscle atrophy, obesity, coronary heart disease, diabetes, insulin resistance, impairments in bowel/bladder function, and pressure ulcers. These medical conditions extract a tremendous toll on veterans and non veterans with SCI, as well as the medical system responsible for their care. Of note, many persons with SCI have significant reduction in quality of life due to loss of home, work, and/or community integration. A robotic exoskeleton suit, the ReWalk, was FDA approved for institutional use in January 2011. This exoskeleton suit is indicated for persons with complete motor paraplegia and this device allows them to stand, walk over ground and to ascend and descend stairs. The device requires the use of arm crutches to maintain balance as the participant stands and ambulates. The VA Rehabilitation Research & Development National Center of Excellence for the Medical Consequences of Spinal Cord Injury at the James J Peters VA Medical Center, Bronx, NY is currently performing a clinical trial to determine the potential benefits of frequent upright standing posture and ambulation on blood pressure and cardiovascular regulation, bowel/bladder function, body composition, metabolism, and quality of life. A brief overview and history of walking devices for SCI and our preliminary findings will be presented. Mobility gains from the exoskeletal device and data from the following mobility measures: 10-meter walk test, 6-minute walk for distance, and the timed up and go will also be presented. The observations and findings to date on the changes in secondary medical consequences of SCI from participation in the exoskeletal walking program will be reported. Is There a Relationship Between Paralympic Classification, Autonomic Symptoms and Altered Cardiovascular Control among Elite Wheelchair Athletes Andrei Krassioukov MD, PhD, FRCPC University of British Columbia (Canada) Low resting arterial blood pressure, episodic hypertension (autonomic dysreflexia, AD), or episodes of orthostatic hypotension (OH) are common among individuals with spinal cord injury (SCI). Paralympic athletes are exposed to tremendous physical and emotional stress during their training and competition. Specifically, athletes with SCI have unique disadvantages during competition due to the nature of their injury, one of which is unstable blood pressure control. Methods: A prospective evaluation of cardiovascular parameters and their correlation with responses to an autonomic questionnaire of 22 Paralympic wheelchair rugby athletes was performed. Data on demographics, neurological injury, and Paralympic classification were also collected. Results: We examined two groups of individuals with complete (AIS A&B, n=11) and incomplete (AIS C&D, n=11) SCI who had similar Paralympic wheelchair rugby classification (1.80 and 1.88 respectively). Individuals with complete SCI very frequently experienced episodes of sweating and headaches (88% and 75% respectively). During training, there was also a significantly high frequency of lightheadedness (63%), fatigue (75%) and blurred vision (38%) among of individuals with complete SCI. Interestingly, both groups of athletes demonstrated presence of OH during evaluation. Conclusion: These data showed that, despite continuous training, symptomatic OH is still common among Paralympians. The presence of OH could interfere with athletic performance and exacerbate fatigue in a subpopulation of athletes. These conditions may explain why wheelchair athletes use “boosting” to increase their blood pressure in order to improve their athletic performance. Research into new ways of classifying athletes of similar impairments and activity or sport limitations gets to the very heart of fair play. A possible addition of autonomic assessment to the athlete evaluations could add a purely technical improvement in the fairness of the class system, team grouping and possibly judging of the results. (Support: C. Neilsen Foundation; Endorsed by International Paralympics Committee). Advancements in the Physiological Evaluation of the High Performance Paralympic Athlete Darren Warburton, PhD University of British Columbia (Canada) This lecture will include an overview of the physiological demands of various Paralympic sports. It will highlight advancements in the assessment of physiological function of high performance athletes. This will include an in-depth analyses of current methodologies employed in the evaluation, training, and rehabilitation of high performance Paralympic athletes. This lecture will critically evaluate currently held axioms and myths in high performance physiology. It will also include an in-depth analysis of the role the cardiovascular system plays in optimal sport performance. At the end of the session, attendees will have a better understanding of recent advancements in the training and physiological assessment of the high performance Paralympic athlete. 19 Objectives • To provide a brief overview of the physiological demands of Paralympic sports. • To provide insight into novel physiological assessment techniques. • To analyze and debate currently held beliefs in high performance physiology. • • • To demonstrate the importance of the cardiovascular system in optimal sport performance. To evaluate critically the current training methodologies used with high performance Paralympic athletes. To highlight areas warranting special consideration when training the high performance Paralympic athlete. therefore, that the disequilibrium between increased demand and reduced capacity of the cardiorespiratory system may conspire to limit exercise capacity in this population. Paralympic Medical Services for the 2010 Paralympic Winter Games Jack Taunton, M.Sc., MD University of British Columbia (Canada) Objective: To present the planning and medical encounters for the 2010 Paralympic Winter Games. Design: Prospective medical encounter study. Setting: 2010 Paralympic Winter Games. Participants: Athletes, coaches, officials, workforce, volunteers, and media. Cardiorespiratory Limitations to Exercise Performance in Paralympic Athletes with Cervical Spinal Cord Injury Christopher West, PhD University of British Columbia (Canada) Over the past 50 years the Paralympics has evolved from a small gathering of 12 athletes to the second largest sporting event in the world that attracts over 4000 athletes from 150 countries. Despite the surge in competitor numbers, research investigating Paralympic athletes is sparse, and the majority of this research has focused on improving technology for the disabled athlete, such as prosthetics and wheelchair design. Few studies have investigated the physiology of elite wheelchair athletes, especially those with cervical SCI who present with the most severe deviation from ‘normal’ homeostasis. Studies in the patient population have demonstrated that individuals with a cervical SCI have reduced aerobic capacity due to a small active muscle mass, an inability to activate the venous muscle pump, and an absence of the sympathetically-mediated adjustments to exercise, including cardiac chronotropy, cardiac inotropy, and redistribution of blood from the splanchnic bed to the locomotor muscles. Such disturbed cardiovascular control may impair central hemodynamics, culminating in a reduced stroke volume, cardiac output, and oxygen uptake. Furthermore, individuals with cervical SCI have weak respiratory muscles, present with a restrictive pulmonary defect, and exhibit dynamic lung hyperinflation during high-intensity exercise. Despite these impairments, the potential of the cardiorespiratory system to limit exercise performance has rarely been investigated, especially in the elite athletic population with cervical SCI. This is surprising since highly-trained athletes with cervical SCI are able to exercise at higher intensities than their untrained counterparts. There is also an additional requirement for many of the respiratory muscles to assist in wheelchair propulsion and postural control. It is plausible, 20 Assessment of Risk Factors: Sport type: alpine, Nordic, and sledge hockey and curling. Participant type: athlete, workforce, and spectators. Terrain and speed. Main Outcome Measures: Medical encounters entered in database at competitive (alpine skiing, biathlon, cross-country skiing, sledge hockey, and curling) and noncompetitive (Whistler and Vancouver Polyclinics, presentation centers, opening and closing ceremonies, media center, Paralympic Family Hotel) venues. Results: Forty-two nations participated with 1350 Paralympic athletes, coaches, and officials. There were 2590 accredited medical encounters (657 athletes, 25.4%; 682 International Federation/National Paralympic Committee officials, 26.3%; 57 IPC, 2.2%; 8 media, 0.3%; 1075 workforce, 41.5%; 111 others, 4.3%) and 127 spectator encounters for a total of 2717 encounters. During the preopening period medical services saw 201 accredited personnel. The busiest venues during the Paralympic Games were the Whistler (1633 encounters) and Vancouver (748 encounters) Polyclinics. Alpine, sledge hockey, and curling were the busiest competitive venues. The majority of medical encounters were musculoskeletal (44.6%, n = 1156). Medical services recorded 1657 therapy treatments, 977 pharmaceutical prescriptions dispensed, 204 dental treatments, 353 imaging examinations (more than 50% from alpine skiing), and 390 laboratory tests. There were 24 ambulance transfers with 7 inpatient hospitalizations for a total of 24 inpatient days and 4 outpatient visits. Conclusions: The mandate to have minimal impact on the health services of Vancouver and the Olympic Corridor while offering excellent medical services to the Games was accomplished. This data will be valuable to future organizing committees. Clin J Sports Med 2012: 22(1):10. Arterial Stiffness on Physically Active Individuals with Spinal Cord Injury Aaron A. Phillips, M.Sc. University of British Columbia (Canada) Through a partnership with the Paralympics and local developmental teams, we aimed to compare arterial stiffness between those with spinal cord injury (SCI) and able bodied (AB) individuals when matched for habitual level of physical activity across a range of participation levels. A total of 17 SCI and 17 AB were matched for sex, age, weight, blood pressure and levels of self reported habitual physical activity (Godin-Shephard). Measures included central (cfPWV) and lower limb (ftPWV) pulse wave velocity and large and small arterial compliance. The cfPWV was significantly elevated (7.3 ± 2.1 vs. 5.7 ± 1.4 m/s, P < 0.05) in the SCI in comparison to AB. No other measures of arterial stiffness were different between groups. In those with SCI, moderate to vigorous physical activity was significantly correlated with both large (r = 0.48, P < 0.05) and small (r = 0.65, P < 0.01) artery compliance, but not cfPWV or ftPWV. Both large and small artery compliance appear to be affected highly by habitual physical activity in active individuals with SCI. However, physical activity does not appear to influence PWV in physically active individuals with SCI. These findings suggest that habitual, wheelchair based physical activity may influence arterial diameter and not stiffness per se. Other factors such as leg mass and sympathetic dysfunction may mediate the increase in arterial stiffness seen in the SCI population. Assessing Autonomic Completeness of Spinal Cord Injury: A Missing Piece of Paralympic Athlete Classification Shirley Wong University of British Columbia (Canada) The standard assessment of spinal cord injury (SCI) (American Spinal Injury Association Impairment Scale (AIS) traditionally evaluated only motor and sensory pathways. Only recently have guidelines for the standard assessment of autonomic function been incorporated into clinical practice. This resulted from recognition of the importance of documenting the impact of SCI on autonomic function, through noted changes in certain organ system functions. A parallel movement to improve International Paralympic Committee (IP) classification to acknowledge autonomic impairments is a current and significantly pressing issue since exclusive use of remaining motor function to classify athletes does not consider conditions that affect the autonomic nervous system. Impaired autonomic function may lead to altered cardiovascular control and for athletes with SCI, this is a major concern since it is well accepted that cardiovascular function and athletic performance are intimately coupled. Autonomic dysfunction may lead to a decrease in heart rate and blood pressure at rest and abnormal cardiovascular responses to exercise. Since the current IPC classification does not consider athletes’ cardiovascular status in their classification, this creates a unique and often disadvantageous situation for athletes with SCI since they are grouped with individuals who have similar motor control but varying degrees of autonomic, and subsequently, cardiovascular control. Analysis of the data we have previously collected on Paralympic athletes reveals that there are autonomic differences amongst athletes with cervical injuries that may either have motor and sensory complete or incomplete injuries. By examining our cardiovascular data and other measures of autonomic function, we have found that motor and sensory completeness of injury is not related to autonomic completeness of injury. This further emphasizes the importance of incorporating autonomic assessment into the classification of athletes to get a better of understanding of all the potential limitations for sport performance in athletes with SCI. Repair and Regeneration of the Injured Spinal Cord with Neural Stem Cells: “Hope or Hype” Michael Fehlings, MD, PhD, FRCSC, FACS Toronto Western Hospital (Canada) The presentation will examine the opportunities and limitations related to the use of neural stem cells as a regenerative strategy for spinal cord injury. New approaches of generating neural stem cells including non-viral IPS strategies will be discussed. Understanding the Challenges to Proving Efficacy with Cell Therapy in Clinical Subjects James D. Guest, MD, PhD, FRCS (C), FACS The Miami Project to Cure Paralysis (United States) Cell therapy is a promising but complex therapy for SCI. Ultimately, cells must be part of the solution to SCI since their complex roles govern nervous system signaling, and they are lost after SCI. There is no “best” cell, different cell types are suited to different aspects of repair. It is not yet clear which SCI patients will experience the most benefit from cell therapies and application in both subacute and chronic subjects has supportive preclinical evidence. The outcomes to be assessed in clinical subjects should mirror those in which preclinical studies showed efficacy. Further, the effectiveness of cell therapy may require that other additional treatments are administered. In the current early stage of testing cell therapy for SCI it is very important that subtle beneficial effects be detectable. Setting expectations too high risks interpreting trial outcomes as falsely negative and leading to premature disillusionment with cell therapy. 21 Preclinical Approaches to Spinal Cord Repair: Transplantation of Schwann Cells Generated from Skin-derived Precursors Wolfram Tetzlaff, PhD University of British Columbia (Canada) Cell transplantation has emerged as an exciting therapeutic approach for spinal cord injury (SCI) in animals, and unproven cell treatments in humans are performed in many centers worldwide. The best candidate cell for transplantation after SCI is intensely debated. We demonstrated previously that skinderived precursors pre-differentiated into Schwann cells (SKPSC) enhance growth and myelination of endogenous axons as well as functional recovery when transplanted 7 days after spinal cord injury (SCI). We envision to develop this approach for autotransplantation which would circumnavigate the need for immunosuppression and therefore tested the efficacy of SKPSC transplantation in the early chronic stage at 8 weeks post injury. This treatment strategy would allow us to harvest skin from a person with acute spinal cord injury undergoing surgery for spine stabilization. Culturing this skin for the generation of Schwann cells will likely take 5-8 weeks. Here we report that SKP-SC transplanted at 8 weeks after a thoracic spinal cord contusion in rats survived and integrated for more than 4 months and arranged in bridges which span these lesions in rostro-caudal direction. Numerous regenerated host axons crossed the host-transplant interface and extended through these bridges, with some re-entering into the spinal cord below the injury. SKP-SC transplantation improved locomotion, (including limb co-ordination and stride length), and reduced abnormal paw rotation and abnormal gait patterns. Post-hoc analysis of the bladders revealed fewer wall thickenings in the SKP-SC group which correlated with improved motor functions. The efficacy of SKP-SC transplantation after chronic SCI opens the door for an autologous treatment approach that greatly enhances the relevance of this candidate therapy for clinical translation. Development of Appropriate Stratification and Outcome Algorithms in Clinical SCI Trials Armin Curt, MD, FRCPC Balgrist University Hospital (Switzerland) Research discoveries and their translation into clinical applications are predominantly hypothesis driven with the assumption that detailed and rather specific drug or cell effects might be achieved that eventually translate into a changed (obviously improved) outcome in patients. Therefore, clinical trial protocols need to meet these specific requirements to allow for a best stratification of patients (patients that will most likely respond successfully to the intervention) and identification of outcome measures that are most sensitive to reveal changes 22 (i.e. improvements) which are considered to be amendable by the specific mode of action. So far most SCI trials apply rather unspecific outcome measures (like ASIA scores) that although are of clinical relevance (albeit MCID issues are not yet resolved) are not able to reveal underlying mechanisms of recovery in SCI. This creates a dilemma where the considered interventions are rather specific (it has to be admitted that in many interventions the main mode of action is at best hypothesized and not necessarily proven) but clinical trial protocols fail to monitor the mode of actions (both in the sense of drug/cell activity and specific consequences in body function). This remains the field in the unfortunate situation that translational information gained in clinical trials mirrored back to basic research are rather weak (if any) and the potential reasons in failures of interventions (like complete failure or insufficient induction of drug/cell activity etc.) can not be discerned which is a requirement to modify interventions for an improved efficacy. In this aspect SCI research falls behind other areas in neuroscience (like MS research) where also surrogates have been successfully introduced to overcome the above mentioned shortcomings. Podium Abstracts Order: Abstracts are listed in order of appearance per the Interdependence 2012 program. Disclosure: No significant relationships for the abstracts listed unless otherwise noted. O1-01 Expectations of Risk, Benefit, and Preclinical Scientific Rigor in Experimental Treatments for Spinal Cord Injury: A Survey of SCI Individuals B.K. Kwon1, A. Ghag1, M. Dvorak1, W. Tetzlaff2, J. Illes3 1 , Combined Neurosurgical and Orthopaedic Spine Program (CNOSP), Department of Orthopaedics, University of British Columbia, Vancouver/BC/CANADA, 2, International Collaboration on Repair Discoveries (ICORD, University of British Columbia, Vancouver/BC/CANADA, 3, Department of Neurology, University of British Columbia, Vancouver/BC/CANADA Background: The question of what preclinical evidence should be generated in order to justify moving an experimental therapy forward to a human SCI clinical trial has yet to be fully addressed.1,2 A recent survey garnered researchers perspectives on the need for safety and efficacy data in animal models and on the importance of independent replication prior to translation.2 We contend that it is also important to consider the perspectives of arguably the most important stakeholder: the individuals who have sustained a SCI.3 As they are ultimately the potential recipients of the experimental therapies, it seems only rational to include their perspectives in the dialogue on translational research.4 Our objective was to determine what potential benefits individuals with SCI would anticipate, what risks they would deem acceptable, and what expectations they would have for the extent of preclinical research done on therapies prior to translation. We also sought to compare these perspectives with those of SCI clinicians. Methods: A survey was distributed to SCI individuals identified through a provincial database. 214 respondents with cervical or thoracic SCI and baseline AIS of A, B, C, or D completed the survey. Results: Individuals with SCI expressed their expectation that experimental therapies were tested in large animal studies and their efficacy independently replicated prior to being advanced into human trials. The majority listed their expectations for “percent chance of recovery” as either 5 to 25% or 25-50%. For invasive cell transplantation trials, while most would require the risk of spinal cord damage, cancer, infection, and nerve pain to be 1% or less, a considerable proportion (15-30%) would participate regardless of the risk of these complications. A greater acceptance of high risk was demonstrated in males, individuals over age 60 years, and in those who described their level of knowledge about SCI research to be high. There was no difference in the proportion of AIS A, B and C individuals willing to accept high or low risk. While they may not understand the details of the science, individuals with SCI have high expectations about the level of preclinical evidence that is supporting therapies that go into clinical trial, although the receptivity to such trials is high. While most of our current trials focus on safety, the respondents of our survey expressed high hopes for the possibility of neurologic benefit. A considerable proportion of individuals are anxious to participate in invasive stem cell trials “regardless of risk”, highlighting their vulnerability to commercial enterprises selling unproven therapies. References: 1. Dietrich WD (2003) Confirming an experimental therapy prior to transfer to humans: what is the ideal? J Rehabil Res Dev 40:63-69. 2. Kwon BK et al (2010) Translational research in spinal cord injury: a survey of opinion from the SCI community. J Neurotrauma 27:21-33. 3. Illes J et al (2011) Stem Cell Clinical Trials for Spinal Cord Injury: Readiness, Reluctance, Redefinition. Stem Cell Rev. 4. Abma TA (2005) Patient participation in health research: research with and for people with spinal cord injuries. Qual Health Res 15:1310-1328. O1-02 PTEN Deletion Promotes Regenerative Sprouting in the Aged Rubrospinal Tract B. Hilton, W. Tetzlaff International Collaboration on Repair Discoveries (ICORD), University of British Columbia, Vancouver/CANADA Background: The paralysis that occurs following spinal cord injury (SCI) is largely the result of transected central nervous system (CNS) axons failing to regenerate. Previous research has indicated that a major contributor to this regenerative failure is a diminished intrinsic capacity of adult CNS axons to grow, based largely on inactivity in the phosphoinositide 3-kinase (PI3K)/ Akt/mammalian target of rapamycin (mTOR) molecular growth pathway, which is negatively regulated by phosphatase and tensin homolog (PTEN) [1,2]. Without activity in this pathway, it is hypothesized that neurons cannot efficiently translate proteins, a key component of axon elongation [3]. By inhibiting PTEN, it may be possible to functionally regenerate CNS neurons following SCI and re-establish connections between the brain and the rest of the body. The rubrospinal tract (RST), which originates in the red nucleus of the midbrain and travels contralaterally in the dorsolateral 23 funiculus of the spinal cord, functions in movement and fails to regenerate after transection. This failure results in paralysis. Here, we assessed whether PTEN deletion would promote axon regeneration in the RST by genetic means, with deletion occurring in aged (7-8 month old) mice. Background: Thoracic rodent models of spinal cord injury (SCI) are the predominate preclinical translational model used [1]; however, cervical SCI represents the majority of clinical cases with highly significant personal impact and societal burden. Methods: Floxed PTEN mice were injected with adenoassociated virus serotype 2 expressing Cre and GFP (AAV2-Cre) or GFP alone for control (AAV2-GFP) into the right red nucleus. Four weeks later, mice underwent a left dorsolateral crush at cervical level C4/C5, transecting the entire RST on this side. Six weeks later, mice were injected with biotinylated dextran amine (BDA) into the right red nucleus to anterogradely trace the RST. Two weeks later, mice were sacrificed, transcardially perfused with fixative, and their spinal cord tissue cryoprotected and cut longitudinally into 20 µM sections. These sections were then immunocytochemically stained for GFP and BDA via standard protocols. Digital images of cervical spinal cord longitudinal sections were collected using a Zeiss Axio-Observer with Yakogawa Spinning-disc confocal device. To quantify axon regenerative sprouting, a horizontal line was drawn through the center of the lesion site and at every 100µM rostral and caudal from the center to a total distance of 1mm rostral and caudal. The number of intersections of BDA- or GFP-labeled fibers with each line was counted on four slides, corresponding to the most dense population of axons in the RST. These values were then normalized to fluorescence intensities at cervical level 1. Methods: The applicability and utility of thoracic and lower cervical SCI preclinical models was evaluated using clip contusion-compression injury paradigm in rats: considered most highly relevant for translation of preclinical data [1]. Spinal injuries were realized in female Wistar rats at the C5, C6, C7 and T7 vertebral levels (controls: laminaectomyonly) using severe clip contusion-compression (28g for 60s). Animals were assessed for 10 weeks using: grip strength meter, Inclined Plane test, WARP contracture scale, BBB locomotor scale, bladder recovery, motor- and somatosensoryevoked potentials (MEP, SEP), and H reflex. LFB/HE histological staining and T1-weighted MR imaging were used to assess tissue loss and cavitation. Adult neural precursor (aNPC) cells were transplanted (2x10^6 cells, or vehicle only) into C6-injured rats at 2 weeks post-injury and followed with similar neurobehavioural assessment. Results: Based on independent analyses of BDA and GFP labeling, AAV2-Cre injected animals showed significantly decreased dieback and increased regenerative sprouting of rubrospinal axons through the lesion site in comparison to AAV2-GFP injected animals, for up to 100µm caudal measured from the middle of the lesion site. References: 1. Park KK, Liu K, Hu Y, Smith PD, Wang C, et a. 2008. Promoting axon regeneration in the adult CNS by modulation of the PTEN/mTOR pathway. Science 322:963-66 2. Liu K, Lu Y, Lee JK, Samara R, Willenberg R, et al. 2010. PTEN deletion enhances the regenerative ability of adult corticospinal neurons. Nat. Neurosci. 13:1075-81 3. Park KK, Liu K, Hu Y, Kanter JL, He Z. 2010. PTEN/mTOR and axon regeneration. Exp. Neurol. 223:45-50 O1-03 Assessment of Cervical Spinal Cord Injury Models: Comparison and Validation Using Extensive Neurobehavioural Assessment and Stem Cell Therapy J. Wilcox, K. Satkunendrarajah, Y. Nasirzadeh, F. Nassiri, M. Fehlings Toronto Western Research Institute, Toronto/ON/CANADA 24 Results: Spontaneous neurological recovery was observed with expected plateaus in all injury groups. Grip strength exhibited marked impairment with C5 and C6 injuries (291+/38g and 566+/-80g, respectively, p 0.01), compared to C7, T7 and laminectomy-only shams (1315+/-65g, 1665+/-49g and 1130+/-50g, respectively) (p 0.0001). Inclined Plane test showed stratification between all groups in grasping and trunk support (p 0.05 between and p 0.0001 among groups). Contracture measured with WARP scale demonstrated significantly higher manual dexterity/utility in C6 compared to C5 rats (p 0.05). No differences were seen in BBB and Subscore. T1-weighted MR revealed similar and overt signal changes in all injuries, as confirmed with quantitative lesion analysis using LFB/H&E. Axonal conduction declined with ascending injury, as measured by peak latency and amplitude (p 0.01) with SEP and MEP. Forelimb spasticity was evident by H/M reflex ratios in C6 and C5 groups. Following aNPC transplantation in C6 animals, grip strength increased 2-fold compared to vehicle controls (417+/-59g vs. 211+/-55g, p=0.007), while Inclined Plane and BBB showed no difference (p=0.15 and 0.88, respectively). Electrophysiology revealed significant improvements to lower peak amplitude and latency in SEP of forelimbs in C6-injured rats compared to controls (p 0.05). Conclusion: The level of injury is highly determinant of forelimb deficit, and precludes using C7 or T7 level injuries to study cervical SCI. The C6 clip paradigm appropriately models neurobehavioural recovery and spasticity of cervical SCI, with utility as a preclinical cervical model exhibited by forelimb recovery following adult NPC transplantation. References: 1) Kwon et al. A Grading System To Evaluate Objectively the Strength of Pre-Clinical Data of Acute Neuroprotective Therapies for Clinical Translation in Spinal Cord Injury. Journal of neurotrauma (2010) O1-04 Objective Spinal fMRI Metrics Distinguish Complete and Incomplete Clinical Grade in Chronic Spinal Cord Injury D. Cadotte1, P.W. Stroman2, D. Mikulis1, R. Bosma2, M.G. Fehlings1 1 , University of Toronto, Toronto/CANADA, 2, Center for Neuroscience Studies, Queen’s University, Kingston/CANADA Background: In an effort to define quantitative spinal cord functional magnetic resonance imaging (fMRI) metrics that can be used to distinguish between ASIA complete and incomplete injury, we compare a cohort of healthy controls to those with chronic SCI (>1 year) who are either complete (ASIA A) or incomplete (ASIA B, C, or D). This is an important step to be able to use quantitative spinal fMRI to follow the integrity of different spinal circuits after injury and during treatment. Here, we investigate the spinothalamic tract. Methods: Using an automated thermal delivery system, heat (44°C) was applied to 2 dermatomes above and 2 below the level of SCI. Spinal fMRI data was collected on a 3T system using a SEEP-based protocol developed by our group (SSFSE, TE=30msec, TR=1sec). Data were spatially normalized and analyzed using the general linear model (P=0.001). We divided the cervical spinal cord into zones based on known anatomical relationships of nerve rootlets entering the cord from the segmental nerve root. We calculated the number of active voxels in the stimulated zones of the spinal cord. Results: 32 people were examined: 20 control, 3 ASIA A complete SCI and 9 incomplete SCI. The average number of active voxels in the dorsal quadrant of the spinal cord zone (corresponding to the dermatome stimulated) was calculated. The average number of active voxels are: (significance set at p< 0.001, 95% confidence interval) Chronic SCI patients: 14 ± 9.4 (complete injury); 10.1 ± 2.5 voxels (incomplete injury) and 4.6 ± 1.9 in healthy controls. Conclusions: This work represents the first attempt to define objective metrics that distinguish between clinical grades of injury. The number of active voxels in the dorsal quadrant of the spinal cord zone (corresponding to the dermatome stimulated) shows a robust ability to distinguish between ASIA complete, incomplete injury and healthy controls. References: Stroman PW. Magnetic resonance imaging of neuronal function in the spinal cord: spinal FMRI. Clin Med Res. 2005 Aug;3(3):146-56. Figley CR, Stroman PW. Development and validation of retrospective spinal cord motion time-course estimates (RESPITE) for spin-echo spinal fMRI: Improved sensitivity and specificity by means of a motioncompensating general linear model analysis. Neuroimage. 2009 Jan 15;44(2):421-7. Stroman PW, Tomanek B, Krause V, Frankenstein UN, Malisza KL. Functional magnetic resonance imaging of the human brain based on signal enhancement by extravascular protons (SEEP fMRI). Magn Reson Med. 2003 Mar;49(3):433-9. O1-05 Elevated Circulating Levels of the Pro-Inflammatory Cytokine Macrophage Migration Inhibitory Factor (MIF) in Chronic Spinal Cord Injury (SCI) Patients. A. Panjwani1, C. Sison2, A. Papatheodorou3, M. Bank4, A. Stein5, O. Bloom6 1 , The North Shore-Long Island Jewish Health System, Great Neck/NY/UNITED STATES OF AMERICA, 2, The North ShoreLong Island Jewish Health System, Manhasset/NY/UNITED STATES OF AMERICA, 3, The Feinstein Institute for Medical Research, Manhasset/NY/UNITED STATES OF AMERICA, 4 , North Shore University Hospital, Manhasset/NY/UNITED STATES OF AMERICA, 5, The Hofstra North Shore-LIJ School of Medicine, Great Neck/NY/UNITED STATES OF AMERICA, 6, Hofstra North Shore LIJ School of Medicine/Feinstein Institute for Medical Research, Manhasset/NY/UNITED STATES OF AMERICA Background: Traumatic spinal cord injury (SCI), which includes all injuries to the spinal cord, conus medullaris and cauda equina, affects more than 12,000 people per year in North America. Both acutely and chronically after SCI, inflammation may deleteriously impact functional recovery(1). The pro-inflammatory cytokine macrophage migration inhibitory factor (MIF) is toxic to spinal neurons in vitro and is elevated acutely in pre-clinical models of SCI(2-4). Genetic deletion of MIF in mice enhances recovery of hind limb function(5). Thus, our hypothesis is that MIF is elevated in patients after SCI, where it is pro-inflammatory. The objective of this study was to measure and compare levels of MIF in chronic SCI and in uninjured subjects. Methods: This prospective pilot study was performed in the outpatient clinic of the Department of Physical Medicine and Rehabilitation within an academic medical center. “Chronic SCI” was defined as at least 12 months from initial injury. Participants included 25 chronic SCI and 25 uninjured subjects. Our Institutional Review Board approved this study; all subjects provided informed consent. SCI subjects included 6 females and 19 males, ages 25-73. Uninjured subjects included 7 females and 18 males, ages 23-62. For SCI subjects, time from initial injury ranged from 1-30 years. Mechanisms of injury included: motor vehicle accident (n=10), fall (n=6), sports (n=3), other (n=2), unknown (n=4). A physiatrist board certified in spinal cord injury medicine evaluated the subjects’ injuries according to International Standards for Neurologic 25 Classification of Spinal Cord Injury (ISNCSCI). The subjects’ ASIA Impairment Scale Grades were: A (n=16), C (n=3), D (n=5) and one was unclassified. MIF was measured in subjects’ plasma using commercially available multiplex cytokine assays. Results: Our results show that SCI subjects exhibited significantly higher levels of MIF than uninjured subjects (median: 1004 v. 567 pg/ml, SCI v. uninjured subjects respectively, P <0.0028 by Mann Whitney test). The MIF interquartile range was 877.6 and 470.2 pg/ml for SCI and uninjured subjects, respectively. These data provide the first evidence that MIF is elevated in the circulation of chronic SCI patients. Inflammatory mediators are hypothesized to contribute to several complications of chronic SCI, including accelerated atherogenesis, increased risk of pressure ulcers, metabolic changes and perhaps, to the non-permissive environment inhibiting nerve regeneration(1). Anti-MIF therapies reduce symptoms in several pre-clinical models of inflammatory diseases(6). Further studies with an increased number of subjects are needed to assess the generality of the present findings and to evaluate the potential utility in pursuing MIF as a therapeutic target for inflammation after SCI. References: 1. Alexander, Popovich Prog Brain Res (2009). 2. Chalimoniuk, et al., Neuroscience (2006). 3. Koda et al., Acta Neuropathol (2004). 4. Yang et al., Brain Res (2006). 5. Nishio et al., Acta Neuropathol (2009). 6. Calandra, Roger Nat Rev Immunol (2003). O1-06 Methods: We generated cDNA expression constructs by cloning the full length chick Sema5B as well as individual TSR- and semaphorin-domains into the pDisplay vector. Stable HEK293 cell lines were transfected with the vectors and cultured with neural tissue explants obtained from E7.5 chicks including dorsal root ganglia (DRG), retinal galion cells (RGCs), and sympathetic ganglia (SG) in order to test the in vitro To test the functions of Sema5B in a physiological condition, we knocked-down its expression in one side of the spinal cord grey matter by electrporating short hairpin RNAs (shRNAs) directed against Sema5B. We then examined the projections of small diameter and proprioceptive sensory axons by immunocytochemically labelling them using antibodies against TrkA or TrkC receptors respectively. Furthermore, by expressing only one of the two domains of Sema5B in HEK293 cells, we showed the semaphorin and TSR domains have opposing functions of attraction and repulsion, respectively. Results: We show that sensory axons of the dorsal root ganglia avoid Sema5B-expressing HEK293 cells in vitro, therefore confirming that Sema5B can function as a guidance cue for these neurons. We also test the function of Sema5B in vivo by electroporating vectors that express short hairpin RNAs targeted against Sema5B into one side of the developing spinal cord grey matter. Immunohistochemical examination of proprioceptive sensory axons show aberrant projections into the side of the spinal cord where Sema5B was knocked down. Thus, Sema5B is a guidance cue that is dynamically expressed throughout the embryonic spinal cord and it plays a critical role in the correct circuit formation of sensory axons during development. Semaphorin 5B is Critical to Axonal Guidance in the Chick Spinal Cord References: Pekarik et al. Nat. Biotechnol. 21, 93-96 (2003). Mendelson and Frank. Neuroscience Let. 138, 72-76 (1992). Messersmith et al. Neuron. 14, 949-959 (1995). Q.Q. Liu1, A. Legg2, W. Wang2, T.P. O’Connor2 1 , Life Sciences Institute, UBC, Vancouver/BC/CANADA, 2, Life Sciences Institute, Vancouver/BC/CANADA O1-07 Background: Semaphorins, characterized by a conserved sema domain at the N-terminus, are a large family of molecules that guide growing axons to their targets during nervous system development. Thus far, little is known about the function of the transmembrane class 5 semaphorins which are distinguished from other classes by the presence of seven type-1 and type-1-like thrombospondin repeats (TSRs) C-terminal to the sema domain. Here we present the expression and function of one class 5 semaphorin, Sema5B, in various regions of the developing chick nervous system. The dynamic expression of Sema5B in the developing spinal cord is particularly intriguing as it appears to correlate with sensory axon targeting in the grey matter. Our research addresses the hypothesis that Sema5B regulates the timing and extent of penetration of sensory axons into the dorsal horn of the developing spinal cord. 26 Creation of an Anatomic Atlas of Cervical Spine Intradural Anatomy Using Fiesta MRI D. Cadotte, D. Mikulis, M.G. Fehlings University of Toronto, Toronto/CANADA Background: We use MRI to visualize the intradural components of cervical spine with optimal CNS / CSF contrast. Clinically, this may be useful to plan operative approaches for intradural pathology and to correlate MR signal changes with functional neurological changes. We have conducted measurements that demonstrate the population variability of the spinal column relative to spinal nerve rootlets. This anatomic atlas will be advantageous for defining precise location of activity when using spinal fMRI. Methods: MRI acquisition: FIESTA, 3T GE magnet; 384 x 384, NEX 2.0, FOV 20, Slice thickness 0.6 mm. Total scan time: approx. 12 min. Images were analyzed using open source software, OsiriX 3.9.2. The ponto-medullary junction (PMJ) and the mid-sagittal bony landmarks of the foramen magnum (FM) are landmarks. Intradural anatomy is compared to vertebral body anatomy in terms of distance from fixed landmarks. Results: N=10; 2 data sets were excluded due to motion. The distance between the PMJ and the FM was relatively constant between subjects (17.4 mm; +/- 0.4 mm). The rostral-caudal extent of nerve rootlets entering the cervical spinal cord was also relatively constant for each level (example: 10.2 mm +/- 0.2 mm at C3; 11.4 mm +/- 0.5 mm at C7). There was considerable heterogeneity between the location where the nerve rootlets enter the cervical spine and the associated vertebral body. The distance from the foramen magnum to the C7 base plate ranged from 104.4 mm to 125.6 mm. The associated position of the entering nerve rootlets ranged from 85.3 mm from the foramen magnum to 99.4 mm. Discussion: This work represents the first attempt at delineating the intradural anatomy of the cervical spinal cord using MRI at 3T. Our study is novel as it outlines the variability between the nerve rootlets (as they enter the spinal cord) and the associated vertebral body. This discrepancy is of fundamental importance to spinal fMRI studies; these methods will help delineate precise locations of neural activity in both SCI patients and controls. References: Lang J, Bartram CT. [Fila radicularia of the ventral and dorsal radices of the human spinal cord]. Gegenbaurs Morphol Jahrb. 1982;128(4):417-62. O1-08 Vegf and Pdgf as an Immunomodulatory Strategy for the Reduction of Secondary Degeneration After a Model Spinal Cord Contusion Injury in Rats B. Goss1, Y.W. Young1, C. Lutton1, R. Williams1, A. MackaySim2 1 , Queensland University of Technology, Brisbane/AUSTRALIA, 2 , National Centre for Adult Stem Cell Research, Griffith University, Brisbane/AUSTRALIA Background: Inflammation in most tissues is initially a protective attempt to facilitate the removal of damaged tissue which ultimately transitions to an anti-inflammatory nature thereby initiating a healing response. However, after spinal cord injury (SCI), the inflammatory response is prolonged and the anti-inflammatory response delayed, leading to secondary degeneration and glial scarring. Based on our previous findings in hemisection injuries [1], we investigated the potential of sustained delivery of vascular endothelial growth factor (VEGF) and platelet derived growth factor (PDGF) to increase early inflammatory events and promote inflammatory resolution and functional changes in a contusion injury model of SCI. Methods: Animal ethics approval was obtained from the Queensland University of Technology. Adult Wistar rats (12-16 weeks old) were subjected to laminectomies 150 kDyne T10 contusion with an infinite horizions impactor. Animals were then randomised to treatment (implantation of osmotic pump (Alzet) loaded with 15μg VEGF & 15 μg PDGF) or control groups (lesion control or lesion plus pump delivering PBS). Rats were sacrificed at one month and the spinal cords were harvested and examined by immunohistology, using antineurofilament-200(NF200) and anti- ionized calcium binding adapter molecule 1 (Iba1) and the chondroitin sulphate proteoglycan NG2. Behaviour was assessed using open field and digigait analysis. One way ANOVA was used for statistic analysis. Results: At 1 month, both high and low dose active pumptreated cords showed a high level of axonal filament throughout the defects. Digigait analysis showed significant improvment in hindlimb base of support, and stride length, while open field BBB score improved with treatment to 17.3±2 compared with control 14.2±1.3 at 2 weeks post injury, indicative of signifcant functional sparing. Animals undergoing a contusion injury also showed that the lesion area was reduced to 5% of the control animals. Iba-1 and NG2 co-staining also showed significant differences in the post-injury inflammatory response and indicating the presence of a novel phenotype of inflammatory cells. References: [1] Combined VEGF and PDGF Treatment Reduces Secondary Degeneration after Spinal Cord Injury Cameron Lutton, Yun Wai Young, Richard Williams, Adrian C.B. Meedeniya, Alan Mackay-Sim, and Ben Goss. J. Neurotrauma. doi:10.1089/neu.2010.1423. O2-01 Exercise Capacity and Tolerance During Inpatient Spinal Cord Injury Rehabilitation: Preliminary Findings C. Pelletier1, G. Jones2, A. Hicks1 1 , Department of Kinesiology, McMaster University, Hamilton/ ON/CANADA, 2, Department of Medicine, McMaster Univeristy, Hamilton/ON/CANADA Background: Although there are physical activity guidelines for adults with chronic spinal cord injury (SCI; >1 year post injury),1 there is limited evidence about exercise and fitness in the acute SCI population. Furthermore, there is currently no protocol in place to determine when it is safe for patients 27 to begin an exercise program after a SCI. The purpose of this study is to describe the exercise capacity and baseline cardiovascular fitness status in a group of adults with acute SCI in an inpatient rehabilitation program. Methods: Twenty participants (mean age 36 ± 12.7 years) were recruited in the final weeks of inpatient SCI rehabilitation (93 ± 43.4 days post injury). Participants were categorized as having either tetraplegia (n = 8, C3-C7, AIS A-D) or paraplegia (n=12, T4-L5, AIS A-D) and completed a physician supervised maximal graded exercise stress test on an arm ergometer. Resistance was increased by 5W/minute for participants with tetraplegia and 10W/minute for participants with paraplegia2 and was terminated if the participant was unable to maintain a cadence of 50 rpm, or reached volitional fatigue. Results: All participants were able to complete the test to volitional fatigue and there were no adverse events or abnormal cardiovascular findings observed with a 12 lead electrocardiogram. Mean absolute VO2peak values were significantly different (p = 0.02) between participants with tetraplegia (0.79 ± 0.30 L/min) and paraplegia (1.10 ± 0.19 L/ min). When expressed relative to body weight, VO2peak values were not significantly different (p = 0.06) between participants with tetraplegia (11.49 ± 3.37 mL/kg/min) and paraplegia (14.97 ± 4.42 mL/kg/min). Time (min:sec) to VO2peak was 6:42 ± 2:48 for the group with tetraplegia and 6:34 ± 1:02 for the group with paraplegia (p = 0.89). Mean respiratory exchange ratio (RER) values of 1.16 ± 0.12 and 1.27 ± 0.15 for participants with tetraplegia and paraplegia (p = 0.09) indicate that participants successfully reached maximal effort. Mean peak heart rate values were significantly different between groups (p = 0.02) with values of 113 ± 21 bpm and 137 ± 20 bpm for participants with tetraplegia and paraplegia, respectively. Findings indicate that exercise is well tolerated in patients with acute SCI in their final weeks of inpatient rehabilitation. Exercise capacity appears to be decreased compared to the chronic SCI population; 2 indicative of significant detraining during the acute/sub-acute rehabilitation process. Further work should aim to develop physical activity guidelines for people with acute SCI and suitable training programs in order to improve physical fitness early in the rehabilitation process. References: 1. Martin Ginis KA, Hicks AL, Latimer AE, Warburton DE, Bourne C, Ditor DS, Goodwin DL, Hayes KC, McCartney N, McIlraith A, Pomerleau P, Smith K, Stone JA, Wolfe DL. The development of evidence-informed physical activity guidelines for adults with spinal cord injury. Spinal Cord 2011; 49:11. 2. Hol AT, Eng JJ, Miller WC, Sproule S, Krassioukov AV. (2007). Reliability and validity of the six-minute arm test for the evaluation of cardiovascular fitness in people with spinal cord injury. Arch Phys Med Rehabil, 88: 489-495. 28 O2-02 Improving Muscle Co-Activation in Spinal Cord Injured Individuals Using Body-Weight Supported Treadmill Training S.S. Lee1, K. Pauhl2, E. Harder1, T. Lam2, J. Wakeling1 1 , Simon Fraser University, Burnaby/CANADA, 2, University of British Columbia, Vancouver/BC/CANADA Background: For individuals with incomplete spinal cord injury (SCI), locomotor training with partial body weight support (PBWS) on a treadmill is a commonly used rehabilitation tool1. The purpose of this study was to investigate whether muscle function and coordination of the primary ankle and knee antagonistic muscles are improved after PBWS training. Using electromyography (EMG), wavelet analysis, a time-frequency decomposition technique, and principal component analysis (PCA), we were able to determine the frequency-dependent correlation between EMG intensities of antagonistic muscles, and to calculate an EMG-normalcy score to evaluate muscle dysfunction3. Methods: We tested individuals (n=7, 42.0±14.3yrs, 1.75±0.12m, 79.7±22.6kg) who had incurred an incomplete spinal cord injury due to a non-progressive lesion above the thoracic level of T10, at least 12 months prior to recruiting to the study. Subjects were tested pre-and post- PWBS Lokomat training. Subjects walked on a treadmill while in a bodyweight supported harness (0 to 50% range, Lokomat) at their comfortable and maximum velocities. EMG data were collected bilaterally: tibialis anterior (TA), medial gastrocnemius (MG), biceps femoris (BF), and rectus femoris (RF). Age-, gender-, and height-matched healthy individuals were also tested at the same % body weight support and velocities as their matched SCI. 50 strides per subject from the pre- and post-training tests were analysed. Intensities of the EMG signals were resolved into time-frequency space using wavelet analysis, 2,3 . The correlation coefficient, r2, was calculated for the EMG intensities between pairs of antagonistic muscles at 10 frequency bands (across the range 19.29Hz to 395.4Hz). An EMG-normalcy score was calculated using PCA. Results: For the TA-MG muscles, the correlation coefficient of pre-training SCI was significantly greater than that of healthy controls (p=0.02)and tended to be greater than that of post-training SCI (Figure 1a). PBSW training decreased the correlation between the MG-TA muscles especially at the midrange frequencies (Figure 1a). Correlation and coordination of the RF and BF also improved after PBWS training (Figure 1b). The EMG normalcy-score was significantly less after training (p=0.03), indicating that muscle function improved during training. We have shown that muscle dysfunction and coordination improves after PBWS treadmill training. Application of this EMG analysis to quantify and evaluate muscle dysfunction and coordination in SCI offers new insights into the fundamental mechanisms behind SCI impaired gait and into the effectiveness of rehabilitation treatments. assessment system that allows simultaneous recording of kinematics and kinetics [2]. Bilateral 3D net joint moments at the wrist, elbow and shoulder were computed [3]. Data obtained from both trials for each SPT technique were averaged. Peak net joint moments were computed during each SPT phases for the three techniques [3] and compared using repeated measures ANOVAs (p < 0.05) with Tukey post-hoc tests performed as needed. References: 1. Barbeau, H and Fung, J (2001) Curr Opin Neurolo. 2. Von Tscharner, V (2000) J Electromyo Kines. 3. Wakeling, JM (2007) Gait and Posture. O2-03 Effects of Varying Forward Trunk Inclination During Sitting Pivot Transfers on Upper Limb Loads in Individuals with a Spinal Cord Injury G. Desroches1, D. Gagnon2, P. Desjardins2, P. Gourdou2, M. Vermette2, S. Nadeau1, M. Popovic3 1 , University of Montreal, Montreal/QC/CANADA, 2, Pathokinesiology Laboratory, Institut de réadaptation GingrasLindsay-de-Montréal, Montreal/QC/CANADA, 3, Rehabilitation Engineering Laboratory, Toronto Rehabilitation Institute, Toronto/ON/CANADA Background: The substantial and repetitive mechanical loads imposed on the upper limbs (U/Ls) during sitting pivot transfers (SPTs) likely contribute to the development and perpetuation of secondary U/L impairments in individuals with spinal cord injury (SCI). Increasing forward trunk inclination while performing SPTs has been proposed as an alternative to reduce mechanical loads imposed on the U/Ls and minimize risks of secondary impairments during SPTs [1]. However, no scientific evidence yet supports this hypothesis. This study aimed to determine the effects of varying forward trunk inclination on the load sustained at the wrist, elbow and shoulder joints during SPTs among individuals with SCI. Methods: Thirty-five individuals who sustained a SCI and use a manual wheelchair as their primary mean of mobility participated in this study (Level of SCI: C4-L4, ASIA: A-D). Participants were asked to perform sitting pivot transfers using three techniques: natural (NAT), exaggerated forward trunk inclination (FLEX) and as close as possible to an upright trunk posture (UP). Two trials were randomly realized for each of the three techniques with the right U/L assuming the leading role. All SPTs were assessed using an instrumented transfer Results: Significant differences were found for peak forward trunk inclination (FLEX > NAT > UP) during all SPT phases across the three conditions. Significant main effects (i.e. technique) were found for net joint moments at the leading and also at the trailing wrist, elbow and shoulder joints. The UP technique yielded higher net joint moment at the wrist and elbow joints but lower at the shoulder joint. Inversely, significant higher shoulder joint net moments were found for the FLEX technique compared to the wrist and elbow. The results of the current study support the hypothesis that forward trunk inclination influences the loads sustained at the U/L joints during SPT [1]. Overall, compare to NAT technique, a FLEX technique reduced the load sustained at the wrist and elbow joints whereas an UP technique minimized loads at the shoulder joints. Thus, from a clinical perspective, it is indicated to teach both alternative techniques (FLEX & UP) to individuals with SCI as compensatory strategies to modulate load distribution at the U/Ls during SPTs. These strategies may allow one to alleviate U/L joint discomfort and to preserve the ability to perform SPTs in individuals with a SCI, for example. References: 1 . Gagnon, D., et al., Clin. Biomech, 2008. 23: p. 279-290. 2. Gagnon, D., et al., J Biomech, 2008. 41: p. 1104-1110. 3. Desroches, G., et al., J Neuroengineering Rehabil, 2011, (in press). O2-04 Exercise Self-Efficacy Following Discharge from Inpatient Spinal Cord Injury Rehabilitation C. Pelletier1, A. Latimer2, A. Hicks1 1 , Department of Kinesiology, McMaster University, Hamilton/ ON/CANADA, 2, Queen’s University, Kingston/ON/CANADA Background: Few studies have evaluated physical activity in the acute spinal cord injury (SCI) population. The weeks surrounding discharge from inpatient SCI rehabilitation might be an ideal to time to implement a physical activity intervention and to promote lifelong participation as patients begin to transition into the community. Social cognitive theory provides a framework that has been shown to predict physical activity participation in people with SCI and includes self-efficacy, selfregulation, and outcome expectations as determinants.1 The 29 purpose of this study was to profile self-efficacy and outcome expectations for physical activity in the months following discharge from rehabilitation. Methods: Twenty participants (mean age 36 ± 12.7 years) with either tetraplegia (n=8, C3-C7, AIS A-D) or paraplegia (n=12, T4-L5, AIS A-D) were recruited in the final weeks of inpatient SCI rehabilitation and were on average 93 ± 43.4 days post injury. With the assistance of a trained interviewer, participants completed a questionnaire to assess physical activity task and scheduling self-efficacy, 1 and outcome expectations.2 Answers were rated on a scale from 1 = strongly disagree to 7 = strongly agree or 1= not at all confident to 7 = completely confident. Results: In terms of outcome expectations, participants most strongly endorsed increased mobility, energy, confidence to perform activities of daily living, self-esteem, and confidence in social situations as benefits associated with being active. There was no significant difference in the composite score for outcome expectations between participants with tetraplegia (6.07 ± 0.79) or paraplegia (5.56 ± 1.00; p = 0.22). Participants in both groups had a high level of scheduling self-efficacy, with mean composite scores of 5.94 ± 1.16 and 5.19 ± 1.23 for participants with tetraplegia and paraplegia, respectively (p = 0.18). Task self-efficacy for aerobic and strengthening activity did not differ between groups. The mean composite scores for participants with tetraplegia were 4.29 ± 1.21 for aerobic physical activity and 4.40 ± 1.69 for strengthening physical activity (p = 0.52). The results for participants with paraplegia were also not significantly different between aerobic (4.54 ± 1.20) and strengthening (4.74 ± 1.30; p = 0.80) physical activity. Taken together, participants had an overall high level of self-efficacy to participate in regular physical activity after being discharged from inpatient SCI rehabilitation regardless of their lesion level. This may be a critical time to provide physical programming so that individuals can act upon their positive thoughts about physical activity. References: 1. Martin Ginis KA, Latimer AE, ArbourNicitopoulos KP, Bassett RL, Wolfe DL, Hanna SE. Determinants of physical activity among people with spinal cord injury: A test of social cognitive theory. Ann Behav Med 2011: 42; 127-133. 2. Latimer AE, Martin Ginis KA, Craven BC. Psychosocial predictors and exercise intentions and behavior among individuals with spinal cord injury. Adapt Phys Act Quart 2004: 21; 71-85. O2-05 Controlled Nerve Lesioning with Direct Current E.N. Ravid, L.S. Gan, A. Prochazka University of Alberta, Edmonton/CANADA Background: One of the most debilitating outcomes of stroke and cervical spinal cord injury is the loss of voluntary hand and arm movement. The reduction of upper extremity function may be further complicated by spastic hypertonus, a chronic reflexive over-activity of muscle nerves. This impedes voluntary movement, causes spasms, contractures and discomfort. Treatments such as stretching or casting, have limited efficacy [1]. Anti-spastic drugs often have side effects such as fatigue and dizziness [2]. Treatment with Botulinum toxin type A (BtA) is costly, may take up to two weeks to take effect and requires repeated administration. A recent study has shown that repeated BtA treatments can cause atrophy in target muscles and in muscles elsewhere in the body [3]. It has long been known that direct current (DC) applied to nerves blocks conduction in large axons, but it was deemed unsuitable for clinical use since it appeared to cause nerve damage. However, it is precisely this aspect that could be of interest clinically. Recently we showed that DC can produce controlled, long-term, graded ablation of nerves and we proposed it as a possible new cost-effective method of treating spastic hypertonus [4]. In the context of SCI rehabilitation, implanted nerve electrodes could be used for two functions: DC ablation and subsequent functional electrical stimulation of the remaining axons. Here we present experimental data exploring the parameters of DC enabling controlled nerve ablation as well as DC ablation following nerve regeneration. Methods: Acute experiments: DC was delivered via a cuff on the tibial nerve in three anesthetized rabbits. The triceps surae muscle was stretched with a muscle puller at 0.08 Hz through its full physiological range. Test muscle twitches were elicited at 2Hz by a more proximal nerve cuff. DC was delivered via a distal cuff in the range of 0.75mA -1mA for varying durations. Chronic experiments: Three cats were implanted with similar nerve cuffs on the common peroneal nerve. DC at levels between 0.3 and 1mA was delivered for periods of up to 40 minutes. Results: Acute experiments: DC amplitudes and durations producing graded attenuation of muscle force were explored. Chronic experiments: In all three cats force was attenuated or completely abolished. It remained attenuated for 6-8 weeks after which it slowly recovered, presumably due to nerve regeneration. In one of the cats, after nerve regeneration, a second administration of DC at 1mA for 9 minutes abolished force again, showing that DC ablation could be repeated successfully. 30 References: 1. Bovend’Eerdt, T.J., et al., The effects of stretching in spasticity: a systematic review. Archives of physical medicine and rehabilitation, 2008. 89(7): p. 1395406. 2. Kita, M. and D.E. Goodkin, Drugs used to treat spasticity. Drugs, 2000. 59(3): p. 487-95. I, et al. Long-term changes in bone metabolism, bone mineral density, quantitative ultrasound parameters, and fracture incidence after spinal cord injury: a cross-sectional observational study in 100 paraplegic men. Osteoporos Int. 2004 Mar;15(3):180-9. Lofvenmark I, Werhagen L, Norrbrink C. Spasticity and bone density after a spinal cord injury. J Rehabil Med. 2009 Nov;41(13):1080-4. 3. Fortuna, R., et al., Changes in contractile properties of muscles receiving repeat injections of botulinum toxin (Botox). Journal of biomechanics, 2011. 44(1): p. 39-44. O2-07 4. Ravid, E.N., et al., Nerve lesioning with direct current. Journal of neural engineering, 2011. 8(1): p. 016005. O2-06 Antiosteoporotic Effects of Alendronate on Younger Patients with Acute Spinal Cord Injury Y.B. Kalke, R. Brenner, H. Reichel SCI Centre Ulm, Orthopaedic Department of the University of Ulm, Ulm/GERMANY Background: Acute spinal cord injury (SCI) is associated with rapid bone loss followed by an increasing risk of fractures. Bisphosponates are used successfully in treating patients with post-menopausal and senile osteoporosis. The question arises whether bisphosphonates have also a positive effect on reduction of early onset osteoporosis in patients with acute SCI and whether there are differences between patients with complete and incomplete status. Quantifying Proprioception In the Lower Limbs Using a Robotic Exoskeleton A. Domingo, C. Cheung, J. Liang, T. Lam University of British Columbia, Vancouver/BC/CANADA Background: Proprioception is a sensory modality that provides information about the position and movement of our limbs in space. It is critical for posture, locomotion [1], motor learning [2] and for negotiating the environment safely and efficiently. Proprioception is often compromised after spinal cord injury (SCI); however, the role of proprioception in the recovery of walking has scarcely been studied. In order to better characterize sensory deficits after SCI and during recovery, it is imperative to use more precise assessment tools. The purpose of this study was to develop a valid and reliable quantitative assessment tool to measure static position sense in the legs using the Lokomat, a robotic exoskeleton. Results: 6 patients were females, 18 males, 8 patients tetraand 16 patients paraplegic > L 1. The average age was 37,3 years. In lumbar spine there was in all patients no significant difference in bone density between the alendronate and the placebo group within 12 months, but in femur T-score decreased significantly in the placebo group of AIS A and B > AIS C and D patients in comparison to the alendronate group. Weekly alendronate seem to have a positive effect on early onset osteoporosis of the femur in younger complete and incomplete paralyzed male and female patients with acute spinal injury. Methods: We used the Lokomat and custom software to assess static position sense in 9 able-bodied (AB) subjects and 7 persons with incomplete SCI (American Spinal Injury Association Impairment Scale level B, C or D). Subjects memorized a target position at either the hip or knee. The Lokomat then moved the test joint to a distractor position. Subjects were then asked to bring the joint back to the target position with a joystick controller. All movements were passive and vision of the legs was obscured. Two hip angles and 2 knee angles were tested, repeated 5 times each. Absolute differences between final and target angles were recorded as errors. Internal validity was assessed by the ability of the test to discriminate between AB and SCI subjects. To measure testretest reliability, subjects were evaluated twice, at least one week apart, and the intra-class correlation coefficient (ICC) comparing errors from each session was calculated. We also performed a clinical test of proprioception in subjects with SCI, where the leg was moved (either the hip or knee) ~10° by an experimenter from a random starting position, and the subject had to indicate whether the movement was “up” or “down.” This was repeated 10 times, and scores were compared to those of the robotic assessment with Spearman’s Rank Order Correlation. References: Zehnder Y, Luthi M, Michel D, Knecht H, Perrelet R, Neto Results: Preliminary data show the test was reliable (ICC: all=0.824; AB=0.644; SCI=0.688, all P<0.004). Hip and Methods: In a prospective, randomised, double blind study 70 mg alendronate or placebo was given weekly to 12 patients with AIS A and B and to 12 patients with AIS C and D 6 weeks after the acute injury for the duration of 12 months. Additionally calcium and vitamin D was administered daily to all patients. Bone mineral density was measured at baseline, 3, 6, 9 and 12 months after injury. 31 knee angle errors (mean±SEM, (°), repeated measures ANOVA) in subjects with SCI (hip: mean=8.94±2.02, SD=6.14±1.01; knee: mean=16.09±2.02, SD=4.44±0.67) were greater (P<0.001) and more variable (P<0.001) than in AB subjects (hip: mean=2.76±0.29, SD=2.04±0.18; knee: mean=3.17±0.31, SD=0.79±0.15). Errors were greater at the knee than at the hip (P=0.004), and an interaction effect (P=0.009) showed that knee errors were greater in SCI subjects. In subjects with SCI, clinical scores were more strongly correlated to robotic assessment scores at the knee than at the hip (knee: r=0.75, P=0.04; hip: r=0.68, P=0.10). This study shows that the Lokomat may potentially be used as a measurement tool for assessing static position sense in persons with incomplete SCI. References: [1] Lajoie Y, Teasdale N, Cole JD, Burnett M, Bard C, Fleury M, Forget R, Paillard J and Lamarre Y. (1996). Gait of a deafferented subject without large myelinated sensory fibers below the neck. Neurology. 47:109-115. [2] Hasan Z. (1992). Role of proprioceptors in neural control. Curr Opin Neurobiol. 2:824-829. O2-08 Online Delphi to Identify Targets for Best Practice Implementation and Associated Performance Measures D. Wolfe1, J. Hsieh1, A. Kras-Dupuis2, K. Campbell1, H. Flett3, C. Koning4, S. SCI KMN Team5 1 , Lawson Health Research Institute, London/ON/CANADA, 2 , St. Joseph’s Health Care London, London/ON/CANADA, 3 , Lyndhurst Spinal Cord Centre, Toronto/ON/CANADA, 4, Glenrose Rehabilitation Hospital, Edmonton/AB/CANADA, 5, ONF RHI APF, Toronto/ON/CANADA Background: The SCI Knowledge Mobilization Network involves six Canadian rehabilitation centres uniformly applying the principles of Implementation Science to facilitate best practice adoption in pressure ulcers, bladder and pain. Consensus development methods enabled identification of initial best practice implementation (BPI) targets and performance measures (PMs) in the area of pressure ulcer prevention and management. Typically, agenda-setting exercises in research or healthcare fall short with respect to utilization of representative and systematic processes. BPI initiatives often have inadequate attention to performance measurement – thereby placing their sustainability at risk. A modified Delphi approach which featured online methods and a collaborative platform was employed to overcome these challenges. Methods: Consensus development and decision-making were achieved via 6 voting rounds over 3 months using an online, modified-Delphi, characterized by the following: • Inclusivity of stakeholders (n = 5 across 6 sites; various disciplines, site leaders, researchers and consumers as well as funding 32 representatives; n = 32) • Provision of evidence-based information including draft CPGs (Houghton et al.-in progress) and the SCIRE evidence-based review (www.scireproject. com) • Use of collaborative platform (Sharepoint) which enabled access to evidence-based resources and betweenround discussions • A priori Delphi rules/principles included anonymous voting, set criteria to guide voting and betweenround decision-making, between-round data synthesis and presentation, continuous monitoring and capability for adaptation Delphi voting rounds: 1: Cull best practice recommendations (BPR) from 45 to 23 2: Rank top 12 BPRs 3: Select top 2 non-negotiable and 3 optional BPRs. 4: Revise/ delete/suggest PMs relating to the BPRs selected in Round 3 5: Cull and rank PMs (small, representative sub-committee) 6: Select final PMs Results: The two priority non-negotiable BPR targets included pressure ulcer-related comprehensive risk assessment and systematic approach to patient education. PMs included indicators to assess the proportion of patients with pressure ulcers during different phases of care as well as the proportion of patients for which a risk assessment is conducted and education is delivered. Also, a patient report survey will assess the effectiveness of the education delivered. The Delphi process laid the foundation to systematically implement and evaluate BPRs and just as importantly, set the stage for a successful BPI initiative that engaged personnel from across the participating sites in establishing a cross-discipline community of practice. References: Jones J, Hunter D. Using the Delphi and nominal group technique in health services research. In Qualitative Research in Health Care, 2nd ed. London: BMJ Books, 2000. URL: http://www.bmjpg.com/qrhc/chapter5.html O3-01 The Brain and Spinal Cord Response to Sensory Stimuli: An fMRI Study R.L. Bosma, C.E. Dobek, M.E. Beynon, P.W. Stroman Center for Neuroscience Studies, Queen’s University, Kingston/ ON/CANADA Background: The ability to see the function of the spinal cord immediately following a spinal cord injury would provide essential information for thorough and accurate assessment of a person’s condition. Currently, this information is not available to doctors, and assessments are based largely on what the patient can report about their condition. Special imaging techniques based on MRI, such as functional magnetic resonance imaging (fMRI) have been used to assess the spinal cord and brain neuronal function. These methods have the potential to dramatically increase the amount of information available to aid in the development of individualized treatment strategies for people with spinal cord injuries. The aim of this study was to use spinal cord and brain fMRI to determine the neural response to sensory stimuli in healthy controls, as a means of providing reference data for patient populations. Methods: Functional MRI studies of the spinal cord, brainstem and brain were carried out in healthy controls (N = 20). Images were acquired in two stages which included areas of overlap, the first spanned the cervical spinal cord and brainstem; the second spanned the brain and upper brainstem (1,2,3,4). During imaging, thermal stimulation of sensory dermatomes was applied at 44 °C to both the right and left shoulders (C5 dermatomes) and hands (C8 dermatomes). Data were analyzed by means of a general linear model (GLM) and connectivity analyses. Results: Results demonstrate that, in the spinal cord, the GLM can be used to distinguish distinct responses to multiple stimuli, while the same analysis does not robustly reveal sensory regions in the brain. However, connectivity calculations projecting from region-to-region, starting from the cord, can identify distributed components of the sensorimotor network in individuals. This study combines spinal cord and brain fMRI to reveal the entire neuroaxis responding to thermal sensory stimulation. The current study lays the foundation for ongoing studies to assess the changes that occur at each of these relay points as a result of trauma. Results from this study contribute to our overall research program which aims to develop fMRI as into a clinical assessment tool in order to provide greater insight to both doctors and patients, guide rehabilitation efforts, and enable better outcome measures for clinical trials of new treatments. References: 1.Stroman, P.W., Bosma, R.L., Tsyben, A. Somatotopic arrangement of thermal sensory regions in the healthy human spinal cord determined by means of fMRI. Magnetic Resonance in Medicine, In Press. 2.Figley, C.R., Leitch, J.K., Stroman, P.W. (2010) In contrast to BOLD: signal enhancement by extravasular water protons (SEEP) as an alternative mechanism of endogenous fMRI signal change. Magnetic Resonance Imaging 3.Figley, C.R., Stroman, P.W. (2009) Development and validation of retrospective spinal cord motion time-course estimates (RESPITE) for spin echo fMRI: Improved sensitivity and specificity by means of a motioncompensating general linear model analysis. NeuroImage O3-02 Influence of Surgical Delay on Hospitalization Costs and Length of Stay Following a Traumatic Spinal Cord Injury J. Mac-Thiong, S. Parent Hôpital du Sacré-Coeur de Montréal, Montréal/CANADA, C. Thompson, �. Bourassa-Moreau, improving the neurological outcome and decreasing the complication rate. From an economic point of view, this could also result in a shorter hospitalization in the Level-I trauma center and, consequently, lower costs for the healthcare system. Thus, the objective of this study was to evaluate the influence of the delay between the spine trauma and the stabilization surgery on the length of stay in the acute care hospital and the associated costs. Methods: A total of 452 adults who sustained a traumatic SCI and had their spinal stabilization surgery done at SacréCœur Hospital between April 2003 and March 2011 were included in this study. Patients were excluded if they were diagnosed with a central cord syndrome associated with pre-existing spinal stenosis, or sustained a spine injury below L1. Socio-demographic and clinical data were retrieved from the Québec Trauma Registry (QTR), which includes all patients that have been treated for a traumatic injury in a healthcare facility in the province of Québec. Costs in CAD$ were calculated using the NIRRU index, obtained through the hospital database. The NIRRU index reflects the financial burden of each patient and the actual length of stay, but excludes physicians’ costs. Costs were then adjusted according to the Canadian rate of inflation between the year of trauma for each patient and 2011. Results: 70 patients underwent spine surgery within the first 24 hours following their traumatic SCI. They were significantly younger and the severity of their trauma, estimated by the ISS, was significantly more important than for patients operated more than 24h after their trauma. When controlling for the differences in age and severity of trauma, patients who had their surgery within 24h post-trauma had a 1-week shorter length of stay in the acute care hospital, which represented an economy of approximately 3500 CAD$ per patient. Decreased delays between spine trauma and stabilization surgery were associated with shorter length of stay in the trauma center, as well as smaller costs. From an economic perspective, an early surgery following a traumatic spinal cord injury is beneficial and results in a lower financial burden on the national healthcare system. This project was funded by the Québec Health Research Fund (FRQS). References: Albert, TJ & Kim, DH. (2005). Timing of surgical stabilization after cervical and thoracic trauma. J. Neurosurg. Spine, 3: 182-190. Dryden, DM, Saunders, LD, Jacobs, P et al. (2005). Direct health care costs after traumatic spinal cord injury. J. Trauma, 59: 441-447. Background: The optimal timing for spinal surgery following a traumatic spinal cord injury is still controversial. There is a trend towards performing the stabilization surgery early after the SCI, which would be beneficial to the patients by 33 O3-03 Responsiveness of a Clinical Impairment Measure Specific for Traumatic Tetraplegia: A MultiCentre Assessment of the Grassp Outcome Measure. S. Kalsi-Ryan1, M. Verrier2, D. Beaton3, M. Popovic2, A. Curt4, M.G. Fehlings1 1 , Toronto Western Hospital, Toronto/ON/CANADA, 2, Rehabilitation Engineering Laboratory, Toronto Rehabilitation Institute, Toronto/ON/CANADA, 3, St. Michaels Hospital, Mobility Program, Clinical Research Unit, Toronto/ ON/CANADA, 4, University Hospital Balgrist, Zürich/ SWITZERLAND Background: GRASSP was developed to capture subtle changes in neurological impairment of the upper extremity after cervical spinal cord injury (SCI) during the acute, subacute, and chronic phases1. The psychometric properties of reliability and validity are well established for the GRASSP with the chronic tetraplegic population2. Responsiveness testing is required as subtle changes in impairment are important because small improvements can have a significant impact on functional independence and may be the only changes occurring when evaluating the development and implementation of emerging therapies. Scientific Aims: 1) To develop the psychometric attribute of responsiveness for the GRASSP Version 1.0; 2) To establish what meaningful change and minimally clinical important differences (MCID) are to the tetraplegic population compared to clinicians and 3) To establish a method to measure neurological impairment and recovery for the upper limb after acute cervical SCI. Methods: A prospective longitudinal study including individuals with acute tetraplegia (C Occiput to T1, AIS A, B, C or D) is currently being conducted as a multi-centre/multi-national study. Serial testing consists of GRASSP, International Standards for Neurological Classification for Spinal Cord Injury (ISNCSCI), Spinal Cord Independence Measure (SCIM), Capabilities of Upper Extremity Questionnaire (CUE), Questionnaires and Life Satisfaction Survey (LISAT-11) administered 0 to 10 days, 1, 3, 6, and 12 months post injury. Analysis for responsiveness will consist of observed change, standardized effect size, and standardized response mean for the following pairs of information: times 2 to 1, time 3 to 1, time 4 to 1, 5 to 1, 2 to 3, 2 to 4, 2 to 5, 3 to 4, 3 to 5 and 4 to 5. Results: Sample: Total enrollment in Ontario to 36, with 6 month follow up for 16 and 12 month follow up for 10. Enrollment in Ontario will close in July 2012, with follow up data collection closing in July 2013. The data have been collected by the GRASSP multidisciplinary research teams at 4 sites of the Ontario Spinal Cord Injury Research Network. Results: Sub-analysis of small datasets within the study show increased sensitivity of the measurement of sensorimotor deficits across the recovery of one year. The GRASSP 34 defines the tetraplegic sample with greater sensitivity than the current “gold standard” and the relationships between GRASSP subtests elucidate functional gains made with greater accuracy. Conclusion: GRASSP Version 1.0 is a sensitive upper limb impairment measure which will be useful in clinical and research settings to assess the sensory, motor and functional changes occurring after injury, with greater sensitivity to the subtle change. This methodology should allow clinicians and researchers to elucidate the underlying approaches to improve concomitant hand function and define efficacy of new interventions. References: Kalsi-Ryan S et al. Top Spinal Cord Inj Rehabil (2009);14(4):34-46 Kalsi-Ryan S et al. J Neurotrauma 2011 Aug 12 (Epub ahead of print) O3-04 Walking Measures Inform SCI Rehabilitation Practice and Research M. Verrier1, K. Guy1, H. Morris1, J. Williams1, A. Marinho1, M. Popovic2, B.C. Craven1, H. Flett1 1 , Toronto Rehabilitation Institute, Toronto/ON/CANADA, 2, Rehabilitation Engineering Laboratory, Toronto Rehabilitation Institute, Toronto/ON/CANADA Background: Walking is a complex sensorimotor function and understanding internal individual patient factors i.e. posture, balance, strength and coordination etc., must be aligned with external environment factors i.e. collision avoidance and attention demands for successful community mobility. The ability to walk is one of the top six articulated goals of individuals with Spinal Cord Injury (SCI) 1 making gait training a major focus of many in-patient and out-patient rehabilitation programs. Therefore, when developing best practices in assessment and therapeutic interventions for walking programs physical therapists always consider the individual, their goals in concert with the specific environments patients will routinely encounter longitudinally. The use of walking measures to characterize patients’ walking status along the recovery continuum informs treatment planning and programming and requires a systematic approach. Methods: The SCIMobility Team at the Toronto Rehabilitation Institute program has developed a standardized approach to the measurement of walking for the purposes of informing treatment planning and delivery and translational research. Over the last five years they have: 1) continuously reviewed the literature for best practices, 2) completed a retrospective study of 180 patient records to determine the feasibility of collection of admission and discharge walking status, 3) developed and trained all physical therapy practitioners to use a standard set of assessments at specific times during the course of recovery, 4) prospectively collected walking data from 62 SCI patients at admission and discharge, 5) collected cross- sectional Gait Rite data (n=52) and 6) captured pre /post-test walking data for an randomized functional electrical therapy trial on a chronic population. Timed measures (10-metre Walk Test (10mWT), 6-Min Walk Test (6MWT) Timed Up and Go Test (TUG) and spatial temporal assessment using Gait Rite (n= and categorical measures of ambulation (Spinal Cord Independence Measure (SCIM III), Walking Index for Spinal Cord Injury (WISCI-II) and the locomotor component of the Functional Independence Measure (FIML) have been routinely captured during rehabilitation stay at admission or when the patient is first able to initiate walking during the course of rehabilitation, at discharge and during outpatient rehabilitation and pre and post interventional trials. Results: Data from selected time points has been analyzed to determine and predict patients’ ability to achieve optimal functional walking levels as measured by velocity and distance coupled with in-home and community mobility profiles for subcohorts of patients. Developing these benchmarks is important for determining the metrics of an “episode of care” for in-/outpatient rehabilitation in an environment where rehabilitation length of stay and readiness for discharge may not always be determined by optimal outcome due to the fiscal pressures for efficiencies. Precisely determining these benchmarks for different cohorts will be important for long-term maintenance of health status and well-being of individuals with SCI caused by both traumatic and non traumatic etiologies. Supported in part by funding from the Ontario Neurotrauma Foundation and the Craig Neilson Foundation. References: 1 Andersen KD. Targeting recovery: priorities of the spinal cord injured population. J Neurotrauma. 2004 21:1371-1383. O3-05 Classifying Neurological Impairment and Spinal Column Injuries: Does Administrative Coding Accurately Represent Clinical Diagnoses? V. Noonan1, N. Thorogood1, B.K. Kwon1, J. Batke2, M. Dvorak1 1 , Rick Hansen Institute, Vancouver/CANADA, 2, Combined Neurosurgical and Orthopaedic Spine Program (CNOSP), Department of Orthopaedics, University of British Columbia, Vancouver/BC/CANADA Background: The International Classification of Diseases (ICD) codes are used to document patient morbidity in administrative databases. Although ICD codes are often used for research purposes, the validity of these codes to accurately capture clinical diagnoses has been questioned.1 We examined the validity of ICD-10 codes compared to the clinical diagnoses for spinal injuries from the Rick Hansen Spinal Cord Injury Registry (RHSCIR). Methods: We compared RHSCIR clinical diagnoses and ICD10 codes from the Discharge Abstract Database (DAD) for patients with traumatic SCI. All patients enrolled in RHSCIR at Vancouver General Hospital from 2004 to 2010 were included. ICD-10 codes used for spinal column and cord injuries were mapped to the RHSCIR spinal column injury diagnosis and the International Standards for Neurological Classification of Spinal Cord Injury, respectively. RHSCIR was applied as the gold standard to estimate validity of the ICD-10 codes with sensitivity, specificity and positive predictive value (PPV). Results: There were 603 participants enrolled in RHSCIR with a spinal cord injury and 341 had a spinal column injury diagnosis. When the RHSCIR diagnoses were compared to the ICD-10 codes from the DAD, 5.3% of the spinal column injuries and 10.9% of the spinal cord injuries were missed with ICD-10 coding. Both the spinal column and cord injuries had highly variable sensitivity (0.140 to 0.868) and PPV (0.070 to 0.865). The most valid column injury ICD-10 code was fractures of cervical vertebrae C3-7 (S12.2); 76.3% (122 of 160) of these fractures in RHSCIR were correctly coded in the DAD. The least valid ICD-10 code was the dislocation of the cervical vertebra (S13.1); only 14.0% (8 of 57) of dislocations of the cervical vertebrae in RHSCIR were correctly coded in the DAD. The most valid cord injury ICD-10 code was the incomplete lesion of the cervical spinal cord (S14.1X); 86.8% (198 of 228) of the incomplete lesions of the cervical spinal cord in RHSCIR were correctly coded in the DAD. The least valid ICD-10 code was the incomplete lesion of the lumbar spinal cord (S34.1X); 66.7% (16 of 24) of incomplete lesions of the lumbar spinal cord in RHSCIR were correctly coded in the DAD. Of all the RHSCIR participants coded with a complete SCI (S14.10, S24.10, and S34.10) in the DAD, 10.5% (22 of 208) had a contradictory incomplete AIS B-D classification based on RHSCIR diagnosis. We have shown that the validity of ICD-10 codes is variable and that ICD-10 codes cannot be reliably used to classify all types of spinal injuries. Compared to previous studies,2, 3 we have reported persons with spinal column and cord injuries that are missed by ICD-10 coding. Prospective clinical registries, such as RHSCIR, should be used if accurate detailed diagnostic data is required. References: 1. van Walraven C et al. Administrative database research infrequently used validated diagnostic or procedural codes. J Clin Epidemiol. 2011;64:1054-1059. 2. Hagen EM et al. Diagnostic coding accuracy for traumatic spinal cord injuries. Spinal Cord. 2009;47:367-371. 3. Thurman DJ et al. Surveillance of spinal cord injuries in Utah, USA. Paraplegia. 1994;32:665-669. 35 O3-06 Rick Hansen Spinal Cord Injury Registry and Ontario Spinal Cord Injury Registry: Relationships Between Respiratory Status and Length-Of-Stay in Acute Care and Rehabilitation. D. Tsui1, B. Drew1, B. Ansley1, L. Macrae1, B.C. Craven2, M. Verrier3 1 , Hamilton Health Sciences, Hamilton/ON/CANADA, 2, Toronto Rehabilitation Institute, Spinal Cord Injury Rehabilitation Program, Toronto/ON/CANADA, 3, Toronto Rehabilitation Institute, Toronto/ON/CANADA Background: Respiratory complications are leading causes of morbidity and mortality in people with spinal cord injury (SCI).1-5 Studies have found a significant relationship between the number of respiratory complications and length-of-stay (LOS), and respiratory variables can explain 60% of variance in acute care LOS.6-7 The Rick Hansen SCI Registry (RHSCIR) and the Ontario SCI Registry (OSCIR) are Canadian databases that store information about traumatic SCI. This study examined the relationship between respiratory status and hospital LOS in adults with traumatic SCI who participated in RHSCIR and OSCIR. Methods: This multicentre prospective cohort study recruited adult patients with traumatic SCI admitted to RHSCIR/OSCIR acute or rehabilitation hospitals in Hamilton and Toronto from April 2007 to May 2009. Respiratory status, neurological status, and hospitalization data of consenting participants were collected by chart review. Data analyses utilized the T-Test and Pearson’s Correlation Coefficient to evaluate the relationship between respiratory status indicators and LOS. Results: One hundred and twenty-four patients consented to participate in the study. All were admitted to acute care and 90 were admitted to rehabilitation. Acute care LOS was significantly longer for participants who required an endotracheal tube for more than 24 hours (n=24) than for participants who did not require an endotracheal tube or used one for 24 hours or less (n=67) [mean(SD): 51(48) vs. 20(16) days; p=0.006]. Participants who required tracheostomy (n=15) had significantly longer acute care LOS than participants who did not require tracheostomy (n=83) [mean(SD): 60(51) vs. 21(18) days; p=0.011]. Rehabilitation LOS was significantly longer for participants who required volume augmentation (n=24) than for participants who did not require volume augmentation (n=40) [mean(SD): 134(78) vs. 81(40) days; p=0.004]. Respiratory function measured by peak cough flow significantly correlated with rehabilitation LOS; participants who had greater peak cough flow were more likely to have shorter rehabilitation LOS (r = −0.538; p=0.001). 36 Respiratory status is related to LOS in acute care and rehabilitation. Improving respiratory care through implementation of best respiratory practices8 may reduce respiratory complications and associated costs. References: 1. Carter RE. Respiratory aspects of spinal cord injury management. Paraplegia. 1987;25:262-266. 2. Devivo MJ, Kartus PL, Stover SL, Phillip RD, Fine R. Cause of death for patients with spinal cord injury. Arch Intern Med. 1989;149:1761-1766. 3. Jackson AB, Groomers TE. Incidence of respiratory complications following SCI. Arch Phys Med Rehabil. 1994;75:270-275. 4. Lemons VR, Wagner FC Jr. Respiratory complications after cervical spinal cord injury. Spine. 1994;19:2315-2320. 5. Winslow C, Rozovsky J. Effect of spinal cord injury on the respiratory system. Am J Phys Med Rehabil. 2003;82:803-814. 6. Winslow C, Bode R, Felton D, Chen D, Meyer PR. Impact of respiratory complications on length of stay and hospital costs in acute cervical spine injury. Chest. 2002;121:1548-1554. 7. Tator CH, Duncan EG, Edmonds VE, Lapczak LI, Andrews DF. Complications and costs of management of acute spinal cord injury. Paraplegia. 1993;31:700-714. 8. Berney S, Bragge P, Granger C, Opdam H, Denehy L. The acute respiratory management of cervical spinal cord injury in the first 6 weeks after injury: a systematic review. Spinal Cord. 2011;49:17-29. O3-07 Prognostic Value of Multimodal Neurophysiological Evaluation in Spinal Cord Injury M. Schubert1, A. Curt1, R. Rupp For The Emsci Study Group2 1 , Spinal Cord Injury Centre Uniklinik Balgrist, Zuerich/ SWITZERLAND, 2, EMSCI Study Network, Klinik für Paraplegiologie, Universitätsklinikum Heidelberg,, Heidelberg/ GERMANY Background: The disability secondary to traumatic spinal cord injury (SCI) is known to be highly variable among patients due to the vast variety of lesion levels and varying severity, resulting in a mixture of central and peripheral neural lesion burden. In this context prognostication of outcome becomes a challenge, yet is paramount in planning rehabilitation and clinical trials. Next to ASIA assessments 1 neurophysiological techniques have been proposed for prognostication as they are objective and early available2. Evoked potentials (EPs) have been used as diagnostic and prognostic tool in SCI 3, although their importance and prognostic value has not been completely established. Methods: The aim of this study was to analyze the prognostic significance of multimodal EPs in a cohort of SCI cases. From the prospective European Multicenter Study about Spinal Cord Injury database (EMSCI ) we evaluated 633 SCI patients who underwent complete neurophysiological evaluation (NPE), including nerve conduction studies, somatosensory and motor EPs within 4 weeks and who were followed for 12 months after SCI. EP abnormalities were quantified through an index of global EP alteration (EP score). The relationship between EP score and disability in terms of Spinal Cord Independence Measure (SCIM)4,5 was analyzed by the Kaplan-Meier survival method and Spearman ρ correlation coefficient. ROC curves were used to determine the best EP score cut off to predict different SCIM endpoints. For each endpoint, sensitivity, specificity, positive and negative predictive values of EP score were calculated. Results: We found a significant correlation (p < 0.0001) between EP score and SCIM total score at the time of NPE and at 3, 6 and 12 months of follow-up, particularly for motor and somatosensory EPs. Multimodal EPs are reliable and objective procedures to predict disability in traumatic SCI patients independent of lesion level and ASIA grade. References: 1 Marino RJ, Barros T, Biering-Sorensen F, Burns SP, Donovan WH, Graves DE, et al. International standards for neurological classification of spinal cord injury. J Spinal Cord Med. 2003 Spring;26 Suppl 1:S50-6. 2 Curt A, Schwab ME, Dietz V. Providing the clinical basis for new interventional therapies: refined diagnosis and assessment of recovery after spinal cord injury. Spinal Cord. 2004 Jan;42(1):1-6. 3 Spiess M, Schubert M, Kliesch U, Halder P. Evolution of tibial SSEP after traumatic spinal cord injury: baseline for clinical trials. Clin Neurophysiol. 2008 May;119(5):1051-61. 4Catz A, Itzkovich M, Steinberg F, et al. The Catz-Itzkovich SCIM: a revised version of the Spinal Cord Independence Measure. Disabil Rehabil. Apr 15 2001;23(6):263-268. 5Catz A, Itzkovich M, Tesio L, et al. A multicenter international study on the Spinal Cord Independence Measure, version III: Rasch psychometric validation. Spinal Cord. Apr 2007;45(4):275-291. O3-08 Outcomes in the Va Sci/D System of Care: Collection, Analysis, Utilization P. Ullrich1, P. Carter2, B. Frazier1, B. Goldstein1, M. Hammond1, R. Hendricks1 1 , Department of Veterans Affairs, Seattle/WA/UNITED STATES OF AMERICA, 2, Department of Veterans Affairs, Seattle/ UNITED STATES OF AMERICA Background: In the United States, the Department of Veterans Affairs (VA) Spinal Cord Injury and Disorder (SCI/D) System of Care provides SCI specialty care to about 21,000 Veterans each year, making the VA one of the largest single networks of SCI care in the world. Central to the mission of the VA SCI/D System of Care (VASSC) is the monitoring of patient outcomes to direct program evaluation and data-driven continuous quality improvement activities. The VA recently launched a program of outcomes collection and utilization at all of the 24 VA SCI Centers nationwide. This presentation describes methods implemented by the VASSC to collect, analyze, and utilize outcomes to improve patient care. The presentation has three primary objectives: 1) describe the novel information technology infrastructure in place to collect and analyze outcomes, 2) describe the outcomes program in place in the VASSC, and 3) report on primary outcomes collected to date. Methods: The VASSC utilizes an innovative user interface called Spinal Cord Injury and Disorders Outcomes (SCIDO). SCIDO is a customized outcomes and assessment application that supports healthcare delivery while facilitating outcomes data collection and utilization for SCI patients. SCIDO is linked to other electronic medical records, allowing SCI providers to access consolidated clinically pertinent information and to coordinate care across sites. SCIDO gives providers tailored displays of outcomes and complications at the level of individual patients or across groups of patients under their care. SCIDO uploads data from all SCI care sites in the VA into a national repository for aggregation and analysis. Outcomes collection in the VASSC involves on-site coordinators at each SCI Center who manage data collection and lead quality improvement efforts. Outcomes data are aggregated and analyzed at a national level and shared with providers and leadership at the SCI Centers. Outcomes are collected from inpatient and outpatient rehabilitation programs, long-term care settings, and from annual evaluations. Outcomes of focus include neurological status, functioning (FIM), community participation (CHARTSF), health status (SF-8), and satisfaction with life (Diener’s SWLS). Results: The primary characteristics of Veterans with SCI/D participating in the program will be highlighted, and key outcomes in this population will be reported. References: Consortium for Spinal Cord Medicine. (1999). Outcomes Following Traumatic Spinal Cord Injury: Clinical Practice Guidelines for Health Care Professionals. Department of Veterans Affairs Office of Public Affairs [home page on the Internet]. Washington (DC): Department of Veterans Affairs; c2009 [updated 2009 Jan; cited 2010 May]. Fact sheet: VA and spinal cord injury; [about 5 screens]. Available from: . Fonseca JE. J Am Paraplegia Soc. 1987;10(1):8-11. O4-01 Spinal Cord Injury Model Systems Database: Continuing 40 Years of Progress Y. Chen, V. Allen, M. Devivo University of Alabama at Birmingham, Birmingham/AL/ UNITED STATES OF AMERICA Background: There has been an increase in collecting and archiving large amounts of information on spinal cord 37 injury (SCI) by federal and non-federal agencies for various purposes. Advances in statistical and information technology have promoted high quality databases, easier access, and potential toward universal global datasets. O4-02 Methods: A systematic review and analysis of the 40-year history of the US Spinal Cord Injury Model Systems (SCIMS) program and associated database was conducted to: 1) summarize history, design, content, data management, data sharing, and current status; 2) identify its strengths, weaknesses, and continued relevance; and 3) evaluate suitability and public availability for future research and collaboration. C. Rivers1, V. Noonan1, K. Walden1, J. Zander1, L. Cartar1, E. Cherban1, B. Sun1, M. Dvorak2 1 , Rick Hansen Institute, Vancouver/BC/CANADA, 2, Combined Neurosurgical and Orthopaedic Spine Program (CNOSP), Department of Orthopaedics, University of British Columbia, Vancouver/BC/CANADA Results: The SCIMS database (https:\\\\www.nscisc.uab. edu) captures data from approximately 13% of new SCI cases that occur in the US every year. Since its inception in 1970, 28 federally funded SCIMS centers across the US have contributed data to the database, including information on demographics, injury characteristics, neurological recovery, medical complications, and psychosocial outcomes. The database is structured longitudinally with data collected during the initial hospitalization and at post-injury 1, 5, 10, and every 5 years thereafter. As of March, 2011, the database included abbreviated registry records on 11,656 patients, more complete initial injury and hospitalization records on 27,969 patients, and 103,758 follow-up records successfully obtained by phone, face-to-face, and chart review and surveyed by mail, with the longest follow-up of 35 years post injury. Although stability and continuity of the database has been a priority, a number of changes have been implemented to meet current needs and reflect changes in health services, health care policy, and new technology. A variety of methods are used to strengthen the quality of the data being reported and maintained in the database, including error checks built into data entry and management software, standardized operation procedures and data dictionary, data collectors training and technical assistance, site visits, on-site quality assurance procedures, and periodical monitoring of enrollment, follow-up, and missing data. Access to the SCIMS database is open to investigators who are within or outside of the SCIMS centers through a standard review and approval process. Strengths include large sample size, use of valid and reliable measures, geographic and patient diversity, long-term outcomes, and rigorous quality control procedures. Limitations include lack of population basis, loss to followup issue, and over-representation of more severe injuries. Conclusion: The SCIMS database remains a valuable resource. Current developments include linkage to other databases to enhance research capability, online tools that allow users to build their datasets and data dictionaries, SCIMS dummy datasets for hands-on experiences, and algorithms and codes for data management and database linkage. References: 1. Stover SL, DeVivo MJ, Go BK. History, implementation, and current status of the National Spinal Cord Injury Database. Arch Phys Med Rehabil 1999; 80:13651371. 2. DeVivo MJ, Go BK, Jackson AB. Overview of the national spinal cord injury statistical center database. J Spinal Cord Med 2002; 25:335-8. 38 The Rick Hansen Spinal Cord Injury Registry: An Update. Background: The Rick Hansen Spinal Cord Injury Registry (RHSCIR) was started in 2002 and was the first nationwide SCI patient-registry within Canada, and includes the International SCI Core Dataset[1]. Currently, RHSCIR has been implemented in 14 cities located in 9 provinces (including 31 acute and rehabilitation centres across Canada) and includes over 1950 individuals who have sustained an acute traumatic SCI. Data are captured from the pre-hospital, acute, and rehabilitation phases of care, and participants are followed in the community at 1, 2, 5 and then every 5 years post-injury. The data collected will provide researchers and clinicians with an invaluable pool of SCI patient information to better understand SCI and the effectiveness of specific treatments, practices or programs for improving functional outcomes and quality of life after SCI. Methods: Aggregate data from all registry participants is presented to provide a description of individuals living with SCI from a Canadian perspective. The RHSCIR data will be compared with data from other large international SCI studies or registries to determine if there are any unique similarities and differences. Preliminary results are presented in this abstract; data presented at the meeting will be updated with the latest available registry information. Results: There are currently over 1950 individuals with traumatic SCI who are participating in the registry. 78.3% of participants are male, 21.7% are female. Mean age at injury is 46.5 years of age; 18.1% are < 25, 15.1% are 25-24, 22.6% are 35-49, 23.1% are 50-64, 21.2% are >/= 65 years of age. Falls accounted for most of the injuries (42.8%), followed by transport accidents (33.7%), sports-related injuries (14.7%), and other causes (8.8%). Falls were more common as the mechanism of injury in older people; transport accidents as the mechanism of injury in younger people. Cervical injuries were the most common (65%), followed by thoracic (22%) and lumbar (13%) injuries. Neurological scores (AIS): 41.9% A (complete), 8.4% B (incomplete), 18.1% C (incomplete), 31.6% D (incomplete). Cervical incomplete injuries (40.9%) are the most prevalent neurological syndrome, followed by thoracic and lumbar complete injuries (17.4%), thoracic and lumbar incomplete injuries (14.7%), cervical complete injuries (13.0%), high cervical complete injuries (10.3%), and cauda equina injuries (3.7%). We will discuss general applications of the data, including investigation of data quality, assisting/ supplementing clinical trials, administrative use for health care management, and development of best practice initiatives. These research topics will demonstrate the value of the registry in improving outcomes and quality of life in people living with SCI. References: 1: Noonan VK, Kwon BK, Soril L, Fehlings MG, Hurlbert RJ, Townson A, Johnson M, Dvorak MF. The Rick Hansen Spinal Cord Injury Registry (RHSCIR): a national patient-registry. Spinal Cord. 2011 Nov 1. O4-03 Review of Knowledge Translation and Implementation Strategies in Spinal Cord Injury V. Noonan1, D. Wolfe2, K. Boily3, N. Thorogood1, S.E. Park1, J. Hsieh4, J. Eng3 1 , Rick Hansen Institute, Vancouver/CANADA, 2, University of Western Ontario, London/ON/CANADA, 3, University of British Columbia, Vancouver/CANADA, 4, Lawson Health Research Institute, London/CANADA Background: Challenges with translating research evidence into the clinical setting are well known. The science of knowledge translation (KT) is relatively new and the factors which ensure the successful implementation of research evidence are still being determined. In the area of spinal cord injury (SCI), projects such as the Consortium for Spinal Cord Medicine have developed clinical practice guidelines, and the Spinal Cord Rehabilitation Evidence (SCIRE) project has conducted over 30 systematic reviews. To facilitate the translation of evidence from these and emerging initiatives into SCI clinical practice, there is a need to identify factors critical for successful implementation and to assess if KT initiatives have impacted clinical outcomes. This study presents a systematic review of the literature and evaluates the KT strategies used throughout the SCI continuum of care (pre-hospital phase to life in the community) and its effect on clinical outcomes. Methods: Four electronic databases MEDLINE/Pubmed, CINAHL, EMBASE and PsycINFO were searched for English studies published from January 1980 to July 2011. Studies were included if there was a SCI KT initiative that described the process of implementation. Two reviewers independently screened the abstracts and consensus was obtained in cases where there was disagreement. The full articles were then acquired and independently reviewed by the same individuals. Articles included in the final selection were abstracted by one of the reviewers. Study quality was independently assigned by two raters using Downs and Black1 for non-randomized control studies and Physiotherapy Evidence Database (PEDro) scale2 for randomized control studies. Results: A total of 2902 publications were identified in the initial search, 94 full articles were reviewed and 20 studies met the inclusion criteria. Strategies used for implementing research evidence included disseminating clinical practice guidelines, incorporating standardized assessments into routine clinical practice and educating clinical staff. Frequently cited barriers included lack of knowledge, time, cost and facilitators were management support, engagement of staff and providing regular feedback. Impact of the implementation on clinical outcomes was only reported in 10 of the 20 studies. Results from this systematic review provide an overview of the state of KT research in SCI. The barriers and facilitators identified in this review may also inform ongoing KT initiatives both in SCI and other health conditions. References: 1. Downs SH, Black N. The feasibility of creating a checklist for the assessment of the methodological quality both of randomised and non-randomised studies of health care interventions. J Epidemiol Community Health. 1998;52:377-384. 2. Sherrington C, Herbert RD, Maher CG, et al. PEDro. A database of randomized trials and systematic reviews in physiotherapy. Man Ther. 2000;5:223-226. O4-04 Intramuscular Diaphragm Pacing for Respiratory Support in Tetraplegics: Current Worldwide Status in 2010. Why Isn’t Available Technology Utilized? R. Onders University Hospitals Case Medical Center, Cleveland/UNITED STATES OF AMERICA Background: Objective: Direct phrenic nerve pacing to replace ventilators for tetraplegics was initially developed in the 1960’s but through the 2000’s less than 5% of the estimated annual 300-500 eligible patients utilized the available devices in the United States (US) (HCUPnet database 1997-2004). Intramuscular diaphragm pacing (DP) was first implanted in 2000, European approval in 2007 and US in 2008. Methods: Design: Review DP patients world-wide and published literature in 2010. Participants/methods: All ventilator dependent spinal cord injured (SCI) patients who were implanted with DP per country and per state in absolute numbers Results: Results: A total of 65 DP implants were done in 9 countries: Canada, France, Norway, Spain, Switzerland, Australia, Saudi Arabia, Jordan and the US. The US total was 43 in 13 states with the majority in only 5 states- Ohio, Colorado, Texas, Illinois and Georgia. In Canada in 2010 all DP implants were done in one province, British Columbia. In 2011, another province implanted DP only when the injured patient’s First Nation local community guaranteed payment. Nine children were implanted worldwide with the youngest age 2. DP technology is being utilized in other respiratory problems and at the largest US site SCI accounts for less than 30% of DP implants. There were 5 peer-reviewed 39 publications on phrenic or DP in 2010 all with positive results. Conclusion: Published research continues to show the clinical benefit of removing patients from mechanical ventilation yet there is still an overwhelmingly low adoption of phrenic or diaphragm pacing. A disparity of technology utilization exists between countries, states or provinces. In the US, individual state Medicaid programs are an obstacle. Recent reports of DP utilization by trauma surgeons early after injury will help expand this technology and decrease ventilator associated pneumonias, diaphragm dysfunction and length of stay. There is also growing experience that early DP implantation has neuroplasticity effects and can help recovery of phrenic motor neuron control and volitional breathing. Fortunately, the expanding use of DP in other diseases such as Amyotrophic Lateral Sclerosis (ALS) will maintain this option for SCI patients. In ALS, DP delays the need for a ventilator by 18 months which improves their quality of life. References: Onders RP, Ponsky TA, Elmo MJ, Lidsky K, Barksdale E. First Reported experience with intramuscular diaphragm pacing in replacing positive pressure mechanical ventilators in Children. J Pediatr Surg. 2011 Jan;46(1):72-6. Onders RP, Khansarinia S, Weiser T, Chin C, Hungness E, Soper N, DeHoyos A, Cole T, Ducko C. Multi-Center Analysis of Diaphragm Pacing in Tetraplegic with Cardiac Pacemakers: Positive Implications for ventilator weaning in Intensive Care Units. Surgery 2010; 148: 893-7 Gonzalez-Bermejo J, MorelotPanzini C, Salachas, F, Redolfi S, Straus C, Becquemin M, Arnulf I, Pradat P, Bruneteau G, Ignagni A, Diop M, Onders R, Nelson T, Menegaux F, Meininger V, Similowski T. Diaphragm pacing improves sleep in patients with amyotrophic lateral sclerosis. Amyotrophic Lateral Sclerosis, 2011 Disclosure: My university, my hospital and myself developed the technology that was used in this abstract O4-05 A Global Perspective on the Frequency of the Leading Causes of Spinal Cord Injury B.M. Sakakibara1, W.C. Miller2, J.C. Furlan3, E. Von Elm4, A. Krassioukov5, -. The Scire Research Team1 1 , University of British Columbia - Graduate Program in Rehabilitation Sciences, Vancouver/BC/CANADA, 2, University of British Columbia - Department of Occupational Sciences and Occupational Therapy, Vancouver/BC/CANADA, 3, Division of Genetics and Development, Toronto Western Research Institute, University Health Network, Toronto/ON/CANADA, 4, Swiss Paraplegic Research Group, Nottwil/SWITZERLAND, 5 , University of British Columbia - Physical Medicine and Rehabilitation, Vancouver/BC/CANADA Background: In many cases, the prevention of spinal cord injuries (SCI) is possible by using safe practices while 40 engaging in various activities . Although significant efforts have been made towards the prevention of SCI, such as developing safety guidelines and policies, as well as education programs, further improvements are possible by identifying and studying the leading causes of SCI around the world. The purposes of this research were to systematically identify and report on the etiology of traumatic SCI in different countries worldwide. Methods: A systematic review of the literature was undertaken to identify the leading causes of SCI around the world. Papers were included for review if they were an epidemiological study reporting on the causation of traumatic SCI among adults (≥18 years), and published between 1949 and 2009 in English in a peer-reviewed journal. The MEDLINE/PubMed, CINAHL, EMBASE and PsycINFO online databases were searched for papers. The reference lists of the relevant papers were also reviewed to identify additional articles that the online database search missed. Results: Despite a lack of uniform SCI data collection and reporting techniques, this review identified the most common causes of SCI around the world to be: 1) motor vehicle crashes; 2) falls; 3) sports; 4) violence; 5) self-harm; 6) work; and 7) natural disasters. Table 1 outlines the review’s findings. Table 1: Cause and Frequency of SCI Cause of SCI: # of studies: Motor vehicle crash 59 Falls 58 Sports 71 Violence 47 Self-harm 19 Work 12 Natural disasters 10 Most studies from: North America, Europe North America, Europe North America, Europe North America, Europe North America, Europe, Asia Europe, Oceania China, Japan, Iran Frequency Minimum: Maximum: Most prevalent: 6.9% (Nepal) 89% (Nigeria) 40.0 – 49.9% 2.2% (Italy) 77.6% (Nepal) 20.0 – 30.0% 1% (Italy) 23.8% (Russia) 7.0 – 16.0% 0.97% (USA) -and- 1% (Germany) 18.9% (USA) -and- 36.0% (South Africa) 1.0 – 9.9% 1.3% (Canada) 25.9% (Greenland) 0.5 – 4.5% 26.8% (Israel) 2.2 – 7.2% 1.2% (China) <1.0% 3% (New Zealand) 0.02% (Japan and Iran) Although this study was thorough in its review, it was limited by the inconsistent data collection and reporting techniques used in the different studies, making it difficult to compare results; a similar concern noted in previous reviews.1-2 In order to truly understand the implications of the differing causes of SCI there is a need for a common approach to evaluate and report on the causes of SCIs worldwide.1 Therefore, future epidemiological studies on SCI are needed to be conducted with common data collection and reporting techniques. Such information will lead not only to greater understanding of worldwide statistics on SCI, but also to better developed international injury prevention programs. References: 1 Ackery A, Tator C, Krassioukov A. A global perspective on spinal cord injury epidemiology. J Neurotrauma 2004;21(10):1355-1370. 2 Wyndaele M, Wyndaele JJ. Incidence, prevalence and epidemiology of spinal cord injury: what learns a worldwide literature survey? Spinal Cord 2006;44(9):523-529. O4-06 Spinal Cord Injury in the Majority World: Challenges and Opportunities in Providing Standard Care A. Burns1, C. O’Connell2 1 , Toronto Rehabilitation Institute, Toronto/ON/CANADA, 2, Stan Cassidy Centre for Rehabilitation, Fredericton/CANADA Background: In the 21st century, acute care and rehabilitation challenges for persons with spinal cord injury (SCI) in lowresource settings remain large, despite significant advances in reducing morbidity and mortality in the developed world. Average survival for a person with paraplegia in developing countries is two years, whereas those with tetraplegia rarely survive initial injury. Progress in improved long-term health and community participation has not been realized globally. This presentation will review global epidemiology and outcomes of spinal cord injury, highlighting the critical challenges and realities impacting delivery of standardized SCI care in the majority of the world. Attention to SCI post disaster has recently resulted in increased awareness and resources directed towards providing standardized SCI care in a number of low-resourced regions; the successful strategies, including registries and training programs, will be described with recommendations on the role of the international SCI community in addressing needs of persons with SCI worldwide. Complications resulting in high mortality both during hospitalization and post-discharge include pressure ulcers and bowel and bladder management. There is poor access to durable medical equipment including wheelchairs. Home and community accessibility limits community reintegration, return to work, and ability to access follow-up care. This is compounded by poor acceptance and recognition of the rights and value of persons with disability in many developing countries. The implementation of training programs in SCI care for local health providers has improved care delivery, enhanced by standardized checklists for key outcomes prior to discharge. Regional and national databases of patients has allowed for patient monitoring post discharge. International attention to SCI in such regions has increased awareness of issues faced by those with injuries, improving advocacy and promoting disability rights initiatives. References: Burns AS, O’Connell C, Landry MD. Spinal cord injury in postearthquake Haiti: lessons learned and future needs. PM&R 2010; 2(8):695-697. Chiu W, Lin H, Lam C, Chu S, Chiang Y, Tsai S. Review paper: epidemiology of traumatic spinal cord injury: comparisons between developed and developing countries. Asia Pac J Public Health 2010; 22(1):9-18. Priebe MM. Spinal cord injuries as a result of earthquakes: lessons from Iran and Pakistan. J Spinal Cord Med 2007; 30(4):367-368. O4-07 Addressing Privacy Requirements for the Development of a National Health Registry in Canada Methods: The International Spinal Cord Society established a Disaster Committee following recent natural disasters with resulting high numbers of persons affected by spinal cord injury (SCI). Tasked with evaluating the current state of SCI care globally, with a focus on low-resourced regions, and establishing a framework for future responses, the authors conducted literature reviews and consultations with both SCI organizations and experts with field and research experience in the developing world. P. Joshi1, V. Noonan1, N. Thorogood1, M.G. Fehlings1, B.C. Craven2, A..G. Linassi3, D.R. Fourney4, B.K. Kwon1, C.S. Bailey5, E. Tsai6, B. Drew7, H. Ahn8, M. Dvorak1 1 , Rick Hansen Institute, Vancouver/CANADA, 2, Toronto Rehabilitation Institute, Toronto/ON/CANADA, 3, University of Saskatchewan, Department of Physical Medicine and Rehabilitation, Saskatoon/CANADA, 4, Division of Neurosurgery, University of Saskatchewan, Saskatoon/ CANADA, 5, London Health Science Centre, London/CANADA, 6 , Ottawa Hospital Research Institute, Ottawa/ON/CANADA, 7 , Department of Surgery, Division of Orthopaedic Surgery, McMaster University, Hamilton/CANADA, 8, St Michael’s Hospital, Toronto/CANADA Results: There is a paucity of information available on epidemiology and outcomes of SCI in the developing world. There is a higher incidence of SCI in the developing world, with falls being a leading cause of injury. Survival rates are poor, particularly for cervical levels of injury. Acute care, including appropriate immobilization, transportation and delays of days before hospital presentation, are major contributors to poor acute outcomes. There is a lack of trained acute care and rehabilitation professionals. Background: Personal health information is one of the most sensitive types of personal information. Inappropriate disclosure of such identifiable information can result in harm and discrimination. In Canada, privacy legislation has addressed concerns regarding personal health information. Both national and provincial privacy legislation influences the collection, management, use and disclosure of personal health information for health research purposes; however, differing interpretations of the legislation has created challenges in 41 forming multi-centre, collaborative, national health research initiatives. We will describe the successful strategies utilized by the Rick Hansen Spinal Cord Injury Registry (RHSCIR) to address the privacy requirements and maintain beneficial health research. Methods: The development of a privacy and security framework at Rick Hansen Institute (RHI) for the operation of RHSCIR and other studies required a series of steps that will be presented. 1) Assessment of privacy requirements 2) Development of a RHI privacy and security strategy 3) Development of a governance structure within RHI 4) Development of standard operating procedures 5) Establishing agreements with RHSCIR sites and researchers 6) Providing a privacy and security training program 7) Undertaking a Privacy Impact Assessment 8) Physical and technical security Results: Based on these steps, a national privacy and security framework was created for the RHSCIR that complied with applicable privacy requirements and integrated the principles of privacy into the technologies, business practices and physical design of the registry. The framework meets a “highwater mark” of best practices in ensuring privacy and security of personal health information across Canada. The lessons learned in the development of this national registry may assist the development of other national or international research initiatives. References: Not applicable O4-08 The Development of Canadian Best Practice Guidelines for the Prevention and Treatment of Pressure Ulcers in the Spinal Cord Injured Population. P. Houghton1, K. Campbell2 1 , University of Western Ontario, London/ON/CANADA, 2, ARGC, Lawson Research, London/ON/CANADA Background: Pressure ulcers are a major complication of spinal cord injury (1). Several evidence-based pressure ulcer guidelines deal with the general population and two guidelines focus on people with spinal cord injury (PVA & SCIRE). Identification of a need for updated guidelines focusing on the Canadian situation prompted the development of these guidelines. Funding was obtained from Ontario Neurotrauma Foundation and Rich Hansen Institute. Building on the solid foundation established by previous guidelines, this document provides a unique Canadian perspective. This guideline aimed to provide experts in spinal cord injury and wound care information they require to deal effectively with this special population. The two project leads: · Develop the framework, process, and scope of the proposed Canadian 42 guidelines · Identify Canadian experts in the relevant disciplines · Invite them to join an interdisciplinary Canadian expert panel and participate in a consensus conference. Methods: A literature search strategy was developed with the assistance of a medical librarian. The CINAHL, EMBASE, PubMed, Scopus, and Cochrane databases were searched. Papers reviewed in the Consortium for Spinal Cord Medicine Clinical Practice Guidelines (2001) or the Spinal Cord Injury Rehabilitation Evidence (SCIRE), Version 2.0 (2008) were excluded from the review list, unless they were pivotal papers. (1,2) Published articles were included in the review list for the new guideline if they included at least 50% spinal cord injury patients in the study population. The articles were divided into topic areas, each of which was associated with specific guideline topics. An expert panel was formed included representatives from consumer advocacy, as well as a variety of health care professionals. The panel had the responsibility of reviewing the spinal cord injury-specific guidelines and the new literature and of identifying any recommendations that should be updated, revised or added to reflect the Canadian context.(1,2) To facilitate this process, the panel was divided into working groups, according to areas of expertise and guideline topic. These groups meet prior to the planned meeting. Results: A two day meeting was held, and group members presented recommendations to the entire panel, to facilitate input and discussion with other specialty areas. The entire panel then reviewed the working group recommendations and came to a consensus on the new guidelines and supporting levels of evidence. Discussion at the meeting demonstrated the need for additional guidelines dealing with 24-hour positioning and support surfaces as well as activity, mobility and conditioning; the steering committee formed two task force, which addressed these topics in more depth. The entire expert panel then reviewed a complete revised draft. After revisions from the entire panel will be incorporated, the document will be circulated to a broad group of stakeholders for external review. The document will then be finalized. References: 1. National Spinal Cord Injury Statistical Center . Annual Report for the Model Spinal Cord Injury Care Systems. Birmingham, AL: NSCISC; 2005. Model Spinal Cord Injury Care Systems. Poster Abstracts Order: Abstracts are listed in order of apperance per the Interdependence 2012 program. Disclosure: No significant relationships for the abstracts listed unless otherwise noted. P1-01 Regaining Functionality Following a Spinal Cord Injury (SCI): Central Issues for SCI Consumers C. Jeanmaire1, J. Horsewell2, H. Sihota2, M. Codyre2 1 , ESCIF (European SCI Federation), EINDHOVEN/ NETHERLANDS, 2, ESCIF (European SCI Federation) Research Working Group, EINDHOVEN/NETHERLANDS Background: Accounts of the history of the treatment of SCI cite the Edwin Smith papyrus (3,000 – 2,500 BC) in which Imhotep, an Egyptian physician, describes the consequences of a spinal cord injury and concludes “an ailment not to be treated (cured)”. In the last century, breakthroughs were made in the comprehensive management of SCI – combating infection, avoiding pressure ulcers, improvements in bladder and bowel management, education and monitoring – making it possible for people to live with SCI. Over the last two decades, a new focus has emerged. Progress in neurological research has presented the possibility that SCI is not an incurable condition and that some degree of functional recovery is possible. Unfortunately, this has also opened a market in “unproven therapies”. Lacking scientific evidence for the results claimed, these therapies harm the progress of good translational science towards functional recovery. Methods: An internet search of advertised therapies and ongoing research into functional recovery after SCI. Ongoing collaboration with other sources, sites and databases to update published material. Results: Information gathered is presented on the SCI research section of www.escif.org. The aim is to provide easily accessible information and guidelines to assist people with SCI who may be interested in undertaking therapies or participating in clinical trials. Discussion: Although the working group discourages participation in “unproven therapies”, it seeks to promote serious, scientific research into SCI regeneration. While the numbers of people with SCI are relatively small – the psychological and financial impact on the individual and family can be enormous. These costs are passed on to the community and to society. The current debate among SCI professionals and consumers tends to underline the following dilemma: should we invest time, money and resources into improving the lives of those with SCI, or should we invest in finding a “cure”? We do not support this “either/or” scenario. While the present generation of SCI consumers may not benefit personally from regenerative research, the issue may be – can we afford NOT to invest in research to find “the cure” for SCI? References: http://www.escif.org/ESCIF,,extra_navi,unproven_ therapies.htm http://www.escif.org/ESCIF,,extra_navi,sci_research.htm P1-02 Patient Advocacy as a Force to Advance SCI Research M. Smith, D. Sullivan Unite 2 Fight Paralysis, Hood River/OR/UNITED STATES OF AMERICA Background: When research scientists, clinicians, investors, and other professionals gather to discuss progress, strategies, and priorities in SCI research, an important voice is often missing - that of persons living with a spinal cord injury. Survivors and their family members have the greatest stake in the pace and direction of research, and they bring a valuable perspective to the conversation. The greatest example of the power of patient advocacy comes from the work of the AIDS community in the United States. Its members took it upon themselves to study the science and the politics behind advancing therapies, and they became empowered by their knowledge. Their activism and pressure on funding and regulatory agencies led to major changes in AIDS clinical trials and drug regulation. Methods: Today we have patient representatives on many FDA (U.S. Food & Drug Administration) advisory committees, but as a group they still struggle to exert influence. At the same time, the California Institute of Regenerative Medicine has embraced the concept of patient advocacy to great effect through its Independent Citizens Oversight Committee. Fully one-third of this decision-making committee is composed of patient advocates. They are a well-educated group that has no special interest to answer to other than finding effective therapies; they ask questions and express urgency on behalf of all those who have life-threatening illnesses. 43 In the SCI community, we have a patient population that can be very difficult to galvanize. From the moment they are injured, survivors are told repeatedly about all the things they cannot do. Living with a spinal cord injury, particularly cervical injuries, is a physical, financial, and emotional drain on patients and family members. It’s hard to find the time or energy for advocacy. Results: On the other hand, if you can impart knowledge and a belief in the promise of science to achieve effective therapies, you have the basis for action. As we watch promising therapies stall on the way to translation due to funding and regulatory hurdles, we believe that an educated, empowered patient advocate community can help overcome these barriers. We must believe and then expect that people living with spinal cord injury can “get smart” about the science and the translational process. It is then up to our leading organizations to provide education and training. Patient advocates can: Appreciate and advise in concert with other disease groups to explore and support common therapies; • Help prioritize the needs and desires of the community; • Question and advise the research, regulatory, and funding individuals and agencies; • Raise money to support targeted SCI research. Spinal cord injury is a life-altering experience to survivors and family members; by nature it takes away ability and power. Advocacy, on the other hand, empowers. If we can offer opportunities whereby SCI survivors have the means to take action and have a voice in determining their future, the research and clinical communities will benefit. References: Duane Roth, A Third Seat at the Table: An Insider’s Perspective on Patient Representatives (Hasting Center Report) publications focused on the causes and management of neuropathic pain (NeP) in individuals with spinal cord injury (SCI). Scoping studies map key concepts in a research area as well as the sources and types of evidence available. Methods: Utilizing the methodology of Arksey and O’Malley (2005), this study has two phases. We are reporting on phase one, in which we undertook a database search with key words ‘neuropathic pain’ and ‘spinal cord injury’. The electronic databases searched included MEDLINE, Embase, CINAHL, CCTR, PsycINFO, AMED, WOS, and SCOPUS from years 1950 to 2009. Data extracted were: author, year, study design, objective, intervention, and study population. The first author (JH) reviewed the abstracts to select studies addressing the research question. Data were then coded by two independent reviewers, based on the criteria listed in the results, below. Results: The MEDLINE search yielded 2,397 articles, of which 926 met inclusion criteria (human in-vivo studies, English, with abstract). Of these 103 were identified as “best fit” to the NeP/SCI question. Data revealed the following numbers: classification/measurement (n=10); descriptive/review (n=29); treatment/pharmacologic (n=20); surgical (n=7); nonpharmacologic (n=6); CNS stimulation (n=6); neuroscience/ mechanism (n=11); personal impact (n=8); patient needs (n=0); predictors/correlates (n=5). Despite NeP being one of the most debilitating secondary medical complications of SCI, research about the cause and care for NeP in this population has been largely neglected. These findings, combined with data from the remaining abstracts, will be used for phase two - stakeholder consultation (with clinicians, policy makers, consumers and their family) to review, assess, and refine the phase one output and identify key research priorities that will inform policy and practice regarding best management strategy for people with NeP after SCI. References: Arksey, H., & O’Malley, L. (2005). Scoping studies: towards a methodological framework. International Journal of Social Research Methodology, 8(1), 19-32. P1-05 Scoping the Field of Research and Management of Neuropathic Pain After Spinal Cord Injury J. Hunter1, T. Jeji2, C.A. Mattison3, Y. Shantharam3, E. Uleryk4, J.L. Henry5 1 , University of Toronto, Toronto/ON/CANADA, 2, Ontario Neurotrauma Foundation, Toronto/CANADA, 3, McMaster University, Hamilton/ON/CANADA, 4, Hospital for Sick Children, Toronto/ON/CANADA, 5, McMaster University, Hamilton/CANADA Background: To conduct a scoping review of the literature to determine the current breadth and depth of the peer-reviewed 44 P1-08 An Inter-Professional Clinical Initiative in an Outpatient Spinal Cord Injury (SCI) Rehabilitation Setting: Pathways to Wellbeing Following SCI Community Reintegration Service S. Haycock, S.L. Hitzig, P. Bain Lyndhurst - Spinal Cord Rehab Program, Toronto Rehab, UHN, Toronto/CANADA Background: Identifiable barriers to community participation post-spinal cord injury (SCI) include reduced employment, limited access to recreational and leisure activities, and a lack of accessible transportation. Equally important are the “invisible” barriers, which stem from attitudes and beliefs of the individual and from society as a whole. For instance, some persons with SCI may not be proactive in community life due to the belief that they are not capable of accomplishing the same things they were able to do pre-injury1. As such, the process of community reintegration requires new learning, problem solving and adaptation to lifestyle changes. To facilitate the coping process, there is a need to provide knowledge about these barriers, and strategies that could be used to help circumvent them. Doing so may lead to better outcomes in relation to individual well-being and quality of life. The objective is to provide an overview of an interprofessional clinical initiative, the Community Reintegration Out-Patient (CROP) Service, which aims to improve well-being in community dwelling persons with SCI (less than 3 years). Methods: The Community Reintegration Out-Patient (CROP) Service is a 12-session, closed psycho-education group, co-facilitated by 2 inter-professional team members, where the clients have opportunities to: 1) discuss topics relevant to emotional, physical and social well-being; 2) learn and understand the role of ‘self’ in the recovery process 3) share experiences and learn from one another within a group setting; and 4) develop a roadmap for improving coping, well-being and overall self management skills while reintegrating back into the community. The group composition is comprised of 10-12 participants, and is guided by group processes. The topics for weekly discussion include: 1) self-care; 2) problemsolving and goal setting; 3) stress management; 4) transition and adjustment; 5) emotions; 6) self-talk; 7) communication and energy management; 8) pain management; 9) happiness and hope; and 10) community resources. The domains of focus across topics are self-esteem, self-efficacy, mood, and coping styles and behaviour. Each session provides each participant an opportunity to share and seek feedback on their goal. A variety of techniques are used to facilitate discussions and accommodate different learning styles including: education, brainstorming, audiovisual devices, creative art, small and large group activities, and experiential learning. In addition, a community outing is organized to allow participants to practice learned concepts in a “real-world” setting. A teaching manual is provided, which includes take home assignments. Results: Although program evaluation is on-going, preliminary reports by participants have been positive regarding the service. As such, the CROP service may provide persons with SCI the skills and knowledge needed to live more active and fulfilling lifestyles post-injury. Noted challenges included managing individual differences within the group, time management, and sustainability due to lack of resources. Overall, the described CROP Service provides a model that can be adapted by rehabilitation professionals at different settings to help persons with SCI better manage emotional, environmental, and social stressors that challenge community participation. References: 1. Boschen KA, Tonack M, Gargaro J. Long-term adjustment and community reintegration following spinal cord injury. Int J Rehabil Res 2003;26:157-64. P1-09 The Case for Transvenous Phrenic Nerve Pacing After a High-Level Spinal Cord Injury A. Hoffer1, L. Tindale1, C. Francis1, R. Meyyappan1, R. Sandoval1, B. Afram1, S. Reynolds2 1 , Simon Fraser University, Burnaby/BC/CANADA, 2, Royal Columbian Hospital, New Westminster/BC/CANADA Background: High-level spinal cord injuries often affect the control of breathing because the diaphragm, the main muscle of inspiration, is innervated by the phrenic nerves that originate from C3-C5. In 50-67% of all acute SCI patients, life is sustained with mechanical ventilation (MV) in intensive care units (ICU). However, MV dependence is known to be associated with acute pulmonary complications such as pressure-induced lung injury, ventilator-acquired pneumonia and nosocomial infections. Recent research indicates that MV and sedation cause rapid, profound disuse atrophy of the diaphragm, with all muscle fibers typically shrinking >50% in the first 3 days (Levine 2008). Diaphragm atrophy is likely to contribute to the high weaning failure rate in ventilator-dependent ICU patients. Furthermore, incomplete SCI patients may have salvageable diaphragmatic muscle fibers which initially atrophy while on MV and may never have the opportunity to regain sufficient strength to breathe independently. Methods: We are developing an intravenous catheter electrode system and method to transvenously activate the phrenic nerves in critically ill patients who depend on MV, with the dual objective of 1) reducing or preventing diaphragm atrophy and 2) greatly reducing the injurious positive pressure that mechanical ventilation inflicts on the lungs, by rhythmically producing negative inspiratory pressure through diaphragmatic activation. The catheter can be installed in a minimally invasive procedure performed under local anesthesia, and easily removed when a patient is ready to wean (Hoffer 2010). Results: We anticipate three categories of high-level SCI survivors who may benefit from our proposed pacing technology. 45 First, SCI patients who did not suffer permanent neurological damage to the diaphragm control system but required MV for several days, may be able to wean sooner from MV if risks of ventilator-associated lung injuries are reduced and diaphragm strength and endurance are preserved by pacing during the acute inflammatory phase. Second, a larger percentage of incomplete SCI survivors may be able to regain voluntary control of breathing if those diaphragm muscle fibers that remain connected can be protected from undergoing rapid atrophy by pacing them during the acute phase. Third, for SCI survivors with irreversible neurological damage who require permanent breathing assistance, an implantable version of our transvascular pacing system may provide more natural, negative-pressure diaphragmatic breathing, similar to surgically implanted systems (Elefteriades, 2002) but requiring only a simple out-patient surgical installation procedure, with no risk of damaging the fragile phrenic nerves and much lower stimulation amplitudes than intramuscular diaphragm electrodes. Our proposed transvascular phrenic nerve pacing approach is expected to benefit many persons who require breathing assistance acutely and/or chronically after SCI, for whom no comparable therapeutic solution is currently available. References: Levine S et al. Rapid disuse atrophy of diaphragm fibers in mechanically ventilated humans. N Engl J Med, 358:1327-35, 2008. Hoffer JA et al. Diaphragm Pacing with Endovascular Electrodes. IFESS 2010 - Int’l. Functional Electrical Stimulation Soc., 15th Ann. Conf., Vienna, Austria, pp 40-42, 2010. Elefteriades J et al., Long-term follow-up of pacing of the conditioned diaphragm in quadriplegia. PACE 25:897-902, 2002. Funded by NSERC I2I and Lungpacer Medical, Inc. Disclosure: I am the founder of Lungpacer Medical Inc., an SFU spin-off R&D company developing a diaphragm pacing system. P1-10 A Kinetic Evaluation of a Novel Forearm Crutch with a Shock Absorption System M. Macgillivray, R. Manocha, B. Sawatzky University of British Columbia, Vancouver/BC/CANADA Background: The forearm crutch enhances control during gait for individuals with mobility impairments (Opila 1987). 46 Forearm crutches have been used by individuals with long-term disabilities for centuries and have been used with increasing frequency, in recent years, for short-term disabilities. Compared to advancements in other forms of assistive devices, such as wheelchairs, the forearm crutch has evolved minimally. An innovative forearm crutch has recently entered the market. The device includes more ergonomic handles and footpads, as well as a shock absorption system that aims to reduce peak forces and impulse. Such modifications are theorized to minimize joint loading. Methods: Thirteen able-bodied individuals (5 males and 8 females) participated in this study. Three different crutches were compared: the SideStix™ Discovery (no shock with a Fetterman™ footpad), the SideStix™ Ultimate (shock with a rotating footpad) and a traditional model (the style sold in pharmacies). Two force plates were used to measure ground reaction forces at the crutch footpads during the body swing phase of swing-through gait. The force plates were sampled at 1000 Hz and data were low-pass filtered with a cut-off frequency of 50Hz using a fourth-order Butterworth filter. Peak force and impulse were normalized to body weight and converted to units of percent body weight. Velocities were calculated for each trial. Each participant’s data was averaged across the 5 trials. Statistics were performed on the averaged data from all 13 able-bodied participants. A repeated measures ANOVA was used to determine differences between crutch types. Data from the left and right sides were combined for statistics involving peak force, impulse and time spent in the body swing-through phase. Bonferroni pairwise comparisons were used to determine which conditions were different when crutch type was significant. Results: Peak Force: There was a significant difference in peak values for braking and propulsive forces between crutch types (F=13.240, p<0.001). The Ultimate crutch demonstrated a significantly smaller peak braking force compared to the Discovery model (p=0.009) and the Traditional model (p=0.001) according to a Bonferonni pairwise comparison. The Ultimate crutch demonstrated significantly greater propulsive force than the Discovery model (p=0.008) and the Traditional model (p<0.001) according to a Bonferonni pairwise comparison. There were no differences in either peak vertical force between the three crutch types (F=2.804, p=0.07) or in peak medial-lateral force between the three crutch types (F=0.027, p=0.973). Impulse: There was a significant difference in vertical impulse between crutch types (F=5.724, p=0.006). The Ultimate crutch had a significantly smaller impulse compared to the Traditional model according to a Bonferonni pairwise comparison (p=0.013). There was no difference in medial-lateral impulse between the three crutch types (F=1.530, p=0.058). Implementing a shock absorption system may provide some benefit to a forearm crutch user. Our study revealed a 17% relative reduction in peak braking force, a 7% increase in peak propulsive force, and a 3% decrease in vertical impulse for the Ultimate crutch (containing a shock system), compared to a typical drugstore model. References: Opila KA, Nicol AC, Paul JP. Forces and impulses during aided gait. Arch Phys Med Rehabil. 1987;68(10):715– 722. Disclosure: I received funding through MITACS for this research internship. The partner organization was SideStix who provided 1/4 of the funding and MITACS provided 1/2. The funding was reviewed and administered through the MITACS Accelerate student program. P1-11 Creating the Winning Conditions to Ensure Sustainable BestPractice Implementation—The Irglm Experience V. Tam1, C. Joly1, M. Laramée1, . SCI KMN2 1 , Institut de Réadaptation Gingras-Lindsay-de-Montréal, Montréal/CANADA, 2, SCI KMN, Toronto/ON/CANADA Background: Continuous Quality Improvement (CQI) is essential for sustaining the adoption of best practices in spinal cord injury (SCI) rehabilitation. An evidence-informed implementation science (IS) framework provides the structure to ensure the continued accuracy (eg. fidelity) of improved practices in the ever-changing real world clinical environment. Through the funding partnership of the Ontario Neurotrauma Foundation (ONF), the Rick Hansen Institute (RHI), and the Alberta Paraplegic Foundation (APF), six SCI rehabilitation centres of excellence across Canada (in three provinces, Quebec, Ontario and Alberta) have engaged in a Community of Practice (CoP) that is focused on implementing best practices in up to three key areas (pressure ulcer prevention, bladder management and pain management). Methodological support of the evidence-informed IS process, is facilitated by the expertise of the National Implementation Research Network (NIRN) of the University of North Carolina. The CoP engaged in a Delphi consensus exercise to select two “best practices” (BP) and associated performance measures (PM) in the prevention and management of pressure ulcers -- risk assessment and patient education. This presentation will describe the organizational transformation experience at IRGLM that includes activities to create a state of readiness for change, and replication and expansion of the best practice implementation (BPI) process into other clinical areas. Methods: Two BPs for the prevention and management of pressure ulcers and associated PMs were agreed upon using a Delphi process that engaged all CoP participants. Based on an IS conceptual framework with guidance from NIRN, a Site Implementation Team (SIT) led by a Transformation Specialist (TS) was assembled to analyse the organizational context and prepare a state of “organizational readiness” for BPI. Despite competing organizational priorities (including a merger-inprogress), commitment at all levels of the organization resulted in very active contribution to the BPI CoP. In addition, the TS/ SIT model was replicated and transposed to other clinical programs in the organization. Results: The TS/SIT model led to the development of a work plan and a site-specific implementation roadmap. This process was replicated with success and a BPI structure now exists in all clinical programs at the IRGLM. References: Fixsen, D. L., Naoom, S. F., Blase, K. A., Friedman, R. M., & Wallace, F. (2005). Implementation research: A synthesis of the literature. Tampa, FL: University of South Florida, Louis de la Parte Florida Mental Health Institute, The National Implementation Research Network. Duda, M., Brown, J. (2011). Important Implementation Reference Slides. National Implementation Research Network. University of North Carolina-Chapel Hill. P1-12 The Effects of Pharmacological Agents on Walking in People with Spinal Cord Injury: A Systematic Review A. Domingo1, A. Al-Yahya2, Y. Asiri2, J. Eng1, T. Lam1 , University of British Columbia, Vancouver/BC/CANADA, 2, King Saud University, Riyadh/SAUDI ARABIA 1 Background: The recovery of walking is an important goal for people with motor-incomplete spinal cord injury (SCI) [1]. Increasing mobility after spinal cord injury can positively impact participation and quality of life, as well as improve cardiovascular health, muscle composition and metabolism, bone health, and psychological well-being [2]. Studies on spinalized animals indicate that some pharmacological agents may act on receptors in the spinal cord, helping to produce coordinated locomotor movement. Other drugs may help to ameliorate neuropathological changes resulting from spinal cord injury (SCI), such as spasticity or demyelination, to improve walking. The purpose of this study was to systematically review the effects of pharmacological agents on gait in people with SCI. Methods: A keyword literature search of articles that evaluated effects of drugs on walking after SCI was performed using the databases MEDLINE/PubMed, CINAHL, EMBASE, PsycINFO and hand searching. Two reviewers evaluated each study, using the Physiotherapy Evidence Database (PEDro) tool for 47 randomized clinical trials (RCT), and the modified Downs & Black scale for other studies. Levels of Evidence were also assigned. Results: Eleven studies met the inclusion criteria. The median PEDro score for RCTs was 7 out of 10, and the median Downs & Black score for non-RCTs studies was 12 out of 28. One RCT provided Level 1 evidence that GM-1 ganglioside combined with physical therapy improved motor scores, walking velocity and distance better than placebo and physical therapy in persons with incomplete SCI. Multiple studies (Levels of Evidence 1-5) showed that Clonidine and Cyproheptadine may improve locomotor function and walking speed in severely impaired individuals with incomplete SCI. Gains in walking speed associated with GM-1, Cyproheptadine, and Clonidine are low compared to those seen with locomotor training. There was also Level 1 evidence that 4-aminopyridine and L-Dopa were no better than placebo in helping to improve gait. Two Level 5 studies showed that Baclofen had little to no effect on improving walking in persons with incomplete SCI. The lower levels of evidence and the small effects of the drugs on walking were in part related to methodological limitations of the reviewed studies. Across studies, the chronicity, level and severity of injury, age, dose and frequency of medications, and outcome measures varied greatly. Most studies also did not take into consideration drug interactions or organ system health of the subjects. Although there is limited evidence so far that pharmacological agents would facilitate walking recovery after SCI, more work should be done that takes these factors into account. In addition, more studies are needed to better understand the effects of drugs combined with other therapies (e.g., gait training and electrical stimulation) on walking outcomes in people with SCI. References: 1. Ditunno, P., et al., Who wants to walk? Preferences for recovery after SCI: a longitudinal and crosssectional study. Spinal Cord, 2008. 46(7): p.500-6. 2. Hicks, A. and K.A. Ginis, Treadmill training after spinal cord injury: it’s not just about the walking. Journal of rehabilitation research and development, 2008. 45(2): p 241-8. P1-13 UTI’s and Intermittent Catheterization, What Does the Evidence Say? T. Hill1, R. Parmar2 1 , CPA Alberta, Calgary/CANADA, 2, Canadian Paraplegic Association (Alberta), Calgary/AB/CANADA Background: Bladder dysfunction (neurogenic bladder) resulting in symptoms of urgency, day and night-time frequency, urinary retention, incontinence and urinary tract infections (UTI) is pervasive issue in spinal cord injury (SCI). UTI has substantial negative psychological effects on 48 individuals and is a major burden on the health care system. Treatment involves non-invasive continence management through toileting, fluid management, containment products, medications, and intermittent catheterization. The purpose of this review of clinical guidelines and best practice literature is to suggest a treatment approach for UTI in the neurogenic bladder for those who are using intermittent catheterization as the primary method of bladder emptying. Methods: Three methods were used to create these educational materials and translate the research evidence into a form useable by consumers and their primary caregivers. First a review of the scientific literature,secondly a working group of consumers and experts formulated the evidence into a UTI prevention brochure and a UTI treatment brochure and supporting background documentation. Thirdly the brochures and the in-depth supporting material was circulated within the expert clinical community where feedback was provided and a consensus was built. Results: Two evidence based pamphlets were developed entitled “Bladder Health For intermittent catheterization users” and Treating Frequent Bladder Infections For intermittent catheterization users”. The supporting evidence resides in a peer reviewed paper entitled “Best practices for the treatment and prevention of UTI in the spinal cord injured population The Alberta Context”. References: 1 De Ridder DJMK, Everaert K, Garcia Fernandez L, et al. “Intermittent catheterisation with hydrophilic-coated catheters (Speedicath) reduces the risk of clinical urinary tract infection in spinal cord injured patients: a prospective randomised parallel comparative trial.” European Urology, August 2005 2005;Article in Press. 2 Cain M, King S, Rink R. “Managing Recalcitrant Urinary Tract Infections in Patients with Bladder Augmentation.” US Pediatrics, 2008: 41, 42. 3 Spinal Cord Injury Rehabilitation Evidence (SCIRE). Bladder Health and Function Following Spinal Cord Injury Version 3.0. Vancouver: SCIRE, 2010, 133. 4 Hooton TM, Bradley SF, Cardenas DD, et al. “Diagnosis, prevention, and treatment of catheter-associated urinary tract infection in adults.” 2009 International Clinical Practice Guidelines from the Infectious Diseases Society of America. Vol. 50. Clin Infect Dis, 2010. 625-63. 5 Moore K, Fader M, Getliffe K. “Long-term bladder management by intermittent catheterisation in adults and children” 2009 The Cochrane Collaboration. Published by John Wiley & Sons, Ltd. 6 Cardenas DD, Moore KN, DannelsMcClure A, Scelza WM, Graves DE, Brooks M, Busch AK. “Intermittent catheterization with a hydrophilic-coated catheter delays urinary tract infections in acute spinal cord injury: a prospective, randomized, multicenter trial.” Physical Medicine and Rehabilitation (PM R), 2011: 3(5):408-17. 7 Consortium of Spinal Cord Medicine. Baldder Management for Adults with Spinal Cord Injury. Clinical Practice Guideline, Washington D.C: Paralyzed Veterans of America, 2006, 50. 8 Casey, R.G., Cullen I.M., Crotty, T., Quinlan, D.M. “intermittent self-catheterization and the risk of squamous cell cancer of the bladder: An emerging clinical entity?” Canadian Urological Association Journal, 2009 3(5) E51-E54. 9 Newman, D.K., Willson M.M. “Review of Intermittent Catheterization and Current Best Practices” Urologic Nursing 2011, 31(1): 12-28. P1-14 The Osteoporosis Guidelines of the Joint Organizations of the GermanSpeaking Bone Research Societies and Their Meaning for Paralyzed Elderly Patients Y.B. Kalke , H. Reichel 1 , SCI Centre Ulm, Orthopaedic Department of the University of Ulm, Ulm/GERMANY, 2, Orthopaedic Department of the University of Ulm, Ulm/GERMANY 1 2 Background: In the German speaking SCI centres an increasing number of elderly patients with spinal cord disease or injury get admitted. A lot of these elderly patients have osteoporosis or are even admitted because of osteoporotic fractures with spinal cord involvement. The guidelines of the joint organizations of the German-speaking bone research societies should be used in this very special patient group. Methods: The subjects of the guidelines are prevention, diagnostic assessment and treatment of osteoporosis in postmenopausal women and in older men. For the special case of glucocorticoid-induced osteoporosis there are separate guidelines. Results: Diagnostic assessment means specific medical history, x-ray, laboratory studies and osteodensitometry with DXA measurements of lumbar spine and femur. In the next step measures like nutrition rich in calcium, evaluation of osteoporosis supporting medication and if necessary further work up of secondary causes are initiated. Depending on vertebral fractures, gender, age, the result of the DXA T-score and on defined risk factors pharmacological treatment with alendronate, ibandronate, zoledronate, raloxifene, risedronate, strontium ranelate or teriparatide together with supplementation of calcium and vitamin D is mandatory. These osteoporosis guidelines should be used definitely in the SCI centres but require special knowledge for diagnostic tools, medical therapy and secondary effects of the different antiosteoporotic drugs. P1-15 Evidence Based Management of Depression Following Spinal Cord Injury: A Meta-Analysis S. Mehta, S. Orenczuk, R. Teasell Lawson Health Research Institute, London/CANADA Background: Objective: To conduct a systematic review and meta-analysis examining the effectiveness of cognitive behavioural therapy for the treatment of depression post SCI. Methods: Medline, CINAHL, EMBASE and PsycINFO databases were searched for all relevant articles published 1980 to February 2010. Studies were selected by two reviewers and were only included for analysis if: ≥ 50% of the subjects had a SCI and study subjects participated in a treatment or intervention involving the treatment of depressive symptoms. Two independent reviewers assessed studies for inclusion criteria. Study results were pooled using a random effects model. was used to calculate standardized mean difference (±SE, 95% CI) for the post treatment effect on depressive symptoms in intervention vs. control groups for each study. Effect sizes were interpreted as: small=0.2, moderate=0.5, large=0.8. Results: Nine studies met inclusion criteria, of these 2 were RCTs, 6 prospective controlled trials and 1 cohort study, with a total pooled sample size of 531. The analysis demonstrated a significant reduction in depressive symptoms in the treatment group compared to the control, with a pooled SMD=0.612±0.152 (95% CI 0.314, 0.910; p=0.0001). Assessment of depressive symptoms was conducted primarily using the BDI and CESD tools. Clinical evaluation of major depressive disorder was present in only 2 studies. Hence, the effect size calculated may be over or under inflated. Conclusion(s): There was moderate evidence for the effectiveness of cognitive behavioural treatment to reduce depressive symptoms following SCI. More comprehensive clinical evaluation should be conducted in order to fully evaluate the effect of this treatment. References: Orenczuk S, Slivinski J, Mehta S, Teasell RW (2010). Depression Following Spinal Cord Injury. In Eng JJ, Teasell RW, Miller WC, Wolfe DL, Townson AF, Hsieh JTC, Connolly SJ, Mehta S, Sakakibara BM, editors. Spinal Cord Injury Rehabilitation Evidence. Version 3.0. References: Zehnder Y, Risi S, Michel, D, Knecht H, Perrelet R, Kraenzlin M, Zach GA, and Lippuner K. Prevention of bone loss in paraplegics over 2 years with alendronate. J Bone Miner Res, July 1, 2004: 19(7):1067-74 Bauman WA, Kirshblum S, CirnigliaroC, Forrest GF, Spungen AM. Underestimation of bone loss of the spine with posterioranterior dual-energy X-ray absorptiometry in patients with spinal cord injury. J Spinal Cord Med. 2010;33(3):214-20 DVO Guideline 2009 for Prevention, Diagnosis and Therapy of Osteoporosis in Adults. Osteologie 2011;20:55-74 49 P1-16 Using Scoping Review Methodology to Conduct a Canadian Spinal Cord Injury (SCI) Rehabilitation Environmental Scan C. Craven1, C. Balioussis2, M. Verrier2, J. Hsieh3, V. Noonan4, A. Raschid5, D. Wolfe3, E. Cherban4 1 , Toronto Rehab, Lyndhurst Centre, Toronto/CANADA, 2, Toronto Rehabilitation Institute-University Health Network, Toronto/ON/CANADA, 3, Lawson Health Research Institute, London/CANADA, 4, Rick Hansen Institute, Vancouver/ CANADA, 5, University of British Columbia, Vancouver/BC/ CANADA Background: To date, there has not been a comprehensive review of Canadian SCI Rehabilitation Service Provision Methods: The Rehabilitation Environmental Scan (E-scan) is a joint translational research project between the Invetigative team, Rick Hansen Institute (RHI) and Canadian Tertiary Academic SCI Rehabilitation Centers. This project informs future service delivery and policy development by first describing the spectrum of current clinical SCI rehabilitation services in Canada, and analyzing the findings for trends and gaps. The final product, the Escan Atlas, will be published in 2012. The content of the Atlas will be organized around 17 rehabilitation goals (e.g., Skin Integrity, Bladder Continence, Mobility, etc.), each presented in a separate chapter. The scoping review methodology employed in the Escan enables triangulation of data from multiple sources. The methodology was based on the York Framework developed by Arksey and O’Malley (2005). Data were obtained from 12 tertiary rehabilitation sites across Canada, and were supplemented and analytically interpreted by content experts and stakeholders (researchers, practitioners, funders, and policy makers). The Atlas will therefore provide an overview of current Canadian patient demographics, site administrative structure, service providers, equipment, and services/programs, local clinical and research expertise, and assessment tools in current use. The research will lead to identification of trends, gaps, and parameters for change. In addition, new research questions will be generated through the amalgamation of information from interpolation of the E-scan data. Key priorities, and best practices in spotlight institutions will be identified. Data elements will be charted, collated, summarized and validated through consultation with content experts and stakeholders to ensure relevance to current Canadian SCI rehabilitation practices. Each Atlas chapter will feature a “Report Card” that will provide priority ratings in each of three domains: Knowledge Generation, Clinical Application, and Policy Change. Ratings will specify where efforts and resources should be directed so that rehabilitation practice can evolve effectively and efficiently by the year 2020. Results: The scoping review methodology used in the E-scan 50 will initiate critical re-evaluation of current SCI rehabilitation practices, thus enabling health care professionals and stakeholders to advance the field thereby enhancing outcomes for the patients we serve. References: Levac D, Colquhoun H, O’Brien KK Scoping studies: advancing the methodology. Implement Sci. 2010 Sep 20;5:69 P1-17 My Life, My Health: Chronic Disease Self-Management Program in Rehabilitation A. Kras-Dupuis1, T. Jeji2 1 , st.joseph’s health care london, London/ON/CANADA, 2, Ontario Neurotrauma Foundation, Toronto/ON/CANADA Background: Background In 2009 the Rehabilitation Program at St. Joseph’s Health Care Parkwood Hospital, with support from the Ontario Neurotrauma Foundation, engaged in establishing a “My Life, My Health” patient self-management program based on the Stanford Chronic Disease Self Management (CDSM) model. Our rehabilitation program delivers service to patients with stroke, spinal cord injury, acquired brain injury, amputation and other neurological conditions. We believed that self-management skills were valuable for people with a spinal cord injury and other similar neurological conditions. We felt that an intervention like the CDSMP could be an effective adjunct to existing patient education and rehabilitation and support patients in taking a more effective, proactive role in better managing the day-to-day challenges of living with a permanent health condition. The major goal of the CDSM model is to empower individuals by increasing their efficacy to take charge and responsibility to manage their health conditions. This process involves the systematic provision of education, to increase individual’s skills and confidence in managing their health and life habits through regular assessment, goal setting, and problem-solving support. Selfmanagement support takes the form of validated evidencebased behaviour change, by developing a personalized, collaborative action plan with specific behavioural goals and tactics for overcoming the barriers to achieve the desired goals. We hypothesized that the CDSM intervention would assist individuals with chronic disability to take responsibility to manage their health and life activities Methods: Methods We designed and delivered the program based on the original CDSMP with respect to the content and process. CDSMP is a six week once a week 21/2 hour program delivered in a group setting. We ensured that the workshop is tailored for maximum accessibility in every respect (time of the day, location, environment, support). We tested the CDSM intervention from these perspectives: · effectiveness across the continuum: from rehabilitation inpatients/recent injuries through outpatients in the community · logistical issues: location (accessibility), scheduling, transportation, contacting participants · customization: branding, language/translation, charts, handouts, incentives, evaluation Results: The “My life, My health” program was designed and delivered as a 6-week series of free interactive workshops facilitated by trained leaders. Over the two year period (20092011) seven workshop series were held at our center. Our evaluation revealed positive impact on those individuals who attended these workshops. We would like to share our experience including: · Workshop participation data · Marketing and recruitment strategies · Facilitation and Leader Training · Evaluation strategies and results · Partnerships with other agencies The “My Life, My Health” program has been featured in several publications. We will share our next steps and plans for sustainability. References: Lorig, K. et al. Effect of a Self-Management Program on Patients with Chronic Disease. Effective Clinical Practice 2001; 4:256-262 Lorig, K. et al. Living a Healthy Life with Chronic Conditions. For Ongoing Physical and Mental Health Conditions. 2010 Canadian Edition: 3d edition Revised and Updated. Hirsche, R. et al. Chronic Disease Selfmanagement for Individuals with Stroke, Multiple Sclerosis and Spinal Cord Injury. Disability and Rehabilitation 2011; 33:1136-1146 Results: • SCI Best-Practice Review using a Delphi Approach – Consumers, clinicians, researchers and decisionmakers participated in an online Delphi consensus panel and identified priority areas for translation into clinical practice including 1) skin care; 2) primary care; and 3) pain management. Potential strategies, barriers and facilitators for implementation were also identified. • Case-Based Continuing Medical Education Modules – A number of case-based modules have been developed to facilitate continuing medical education of health care professionals across a variety of disciplines and settings. • SCI Outcome Measures Toolkit – An online Delphi consensus panel involving a variety of stakeholders identified the key outcome measurement tools for SCI rehabilitation which would be pragmatic and relevant to clinicians and researchers alike. Conclusion: SCIRE (www.scireproject.com), even though relatively new, has enabled the development of specific initiatives designed to facilitate adoption of better clinical practice in SCI rehabilitation. Development of other initiatives that promote best practice among using SCIRE as a platform will result in improved outcomes for individuals with SCI. References: Eng JJ, Teasell RW, Miller WC, Wolfe DL, Townson AF, Hsieh JTC, Connolly SJ, Mehta S, Sakakibara BM, editors. Spinal Cord Injury Rehabilitation Evidence. Version 3.0. P1-18 Scire 3.0: A Platform for Developing Initiatives to Enhance Practice S. Mehta1, D. Wolfe1, J. Eng2, R. Teasell1, W. Miller2, A. Townson2, J. Hsieh1, B.M. Sakakibara3, S. Connolly1 1 , Lawson Health Research Institute, London/CANADA, 2 , University of British Columbia, Vancouver/CANADA, 3, University of British Columbia - GF Strong Rehabilitation Research Lab, Vancouver/BC/CANADA Background: Purpose and Relevance: To illustrate the utility of the Spinal Cord Injury Rehabilitation Evidence (SCIRE) systematic review as a platform to enable best practice adoption by describing 3 SCIRE-based knowledge mobilization projects. Methods: Abstract Overview: SCIRE, recently updated (Version 3.0), is a systematic review of SCI rehabilitation evidence incorporating over 1000 studies (including > 200 RCTs). Bottom line evidence-based statements have been created for interventions across 23 topic areas to facilitate knowledge mobilization by clinicians. Three initial initiatives based on SCIRE include: P1-19 Gabapentinoids are Effective in Decreasing Neuropathic Pain Intensity post SCI: A Meta-Analysis S. Mehta1, A. Mcintyre1, K. Salter1, C. Short2, K. Cheung1, J. Hsieh1, D. Wolfe1, R. Teasell1 1 , Lawson Health Research Institute, London/CANADA, 2, Dalhousie University, Halifax/CANADA Background: Purpose: This meta-analysis examines the effectiveness of gabapentinoids (gabapentin and pregabalin) in improving neuropathic pain in individuals with spinal cord injury (SCI). Relevance: Pain has a negative impact on quality of life in an individual with SCI quality of life. Hence, it’s important to determine effective treatment as a part of evidence based practice. Methods: Methods: A systematic search was conducted using Medline, CINAHL, EMBASE and PsycINFO databases for all relevant articles published 1980 to March 2010. Randomized controlled trials (RCTs) involving gabapentinoids in the treatment of neuropathic pain post SCI, with at least 3 individuals with SCI and ≥ 50% of study population with SCI. 51 Two independent reviewers assessed study quality using the PEDro assessment scale. Study results were pooled using a random effects model. was used to calculate standardized mean difference (±SE, 95% CI) for the post treatment effect on pain intensity assessed in intervention vs. control groups for each study. Effect sizes are commonly interpreted as: small=0.2, moderate=0.5, large=0.8. Results: Results: 5 RCTs (3 crossover and 2 parallel study designs) met inclusion criteria providing a total pooled sample size of 226 individuals. Pooled analysis demonstrated a significant reduction in the intensity of neuropathic pain associated with gabapentinoid treatment compared to placebo. The pooled SMD was 0.797±0.114 (95% CI 0.574,1.02; p=0.0001). Funnel plot analysis revealed no significant publication bias (Egger’s regression intercept=x; p=0.67). References: Teasell RW, Mehta S, Aubut J, Foulon BL, Wolfe DL, Hsieh JTC, Townson AF, Short C (2010). Pain Following Spinal Cord Injury. In Eng JJ, Teasell RW, Miller WC, Wolfe DL, Townson AF, Hsieh JTC, Connolly SJ, Mehta S, Sakakibara BM, editors. Spinal Cord Injury Rehabilitation Evidence. Version 3.0. sizes were interpreted as: small=0.2, moderate=0.5, or large=0.8. Results: Eleven studies, (5 controlled, 6 uncontrolled) representing data from 484 subjects were included. Post BTX A injection, large treatment effects were observed in post-void residual urine volume, reflex volume, bladder capacity, bladder compliance, and catheterization frequency (p<0.0001). Rate of incontinence episodes was reduced from 23% to 1.31% post BTX-A treatment. No significant improvement in max flow rate was observed (p=0.403). Conclusion: Results of the metaanalysis indicate BTX-A is effective in treating bladder filling dysfunction post SCI. The use of BTX-A was associated with a decrease in incontinence episodes, catheter use and bladder pressures. References: Wolfe DL, Ethans K, Hill D, Hsieh JTC, Mehta S, Teasell RW, Askes H (2010). Bladder Health and Function Following Spinal Cord Injury. In Eng JJ, Teasell RW, Miller WC, Wolfe DL, Townson AF, Hsieh JTC, Connolly SJ, Mehta S, Sakakibara BM, editors. Spinal Cord Injury Rehabilitation Evidence. Version 3.0. Vancouver: p 1-19. P1-21 P1-20 Effectiveness of Botulinum Toxin in Treating Neurogenic Detrusor Overactivity post SCI: A Systematic Review and Meta-Analysis S. Mehta1, D. Hill2, A. Mcintyre1, N. Foley1, D. Wolfe1, J. Hsieh1, K. Ethans3, E. Loh1, R. Teasell1 1 , Lawson Health Research Institute, London/CANADA, 2, Foothills Hospital, Calgary/CANADA, 3, University of Manitoba, Winnipeg/CANADA Background: To examine the effectiveness of botulinum toxin (BTX) on neurogenic detrusor overactivity in individuals with spinal cord injury (SCI). Methods: Medline, CINAHL, EMBASE and PsycINFO databases were searched for all relevant articles published from 1980 to October 2011. Ttrials examining the use of BTX-A injections into the detrusor wall in treatment of bladder filling post SCI were included if ≥ 50% of study sample was comprised of subjects post SCI, outcomes of interest were assessed before and after treatment with a single injection of BTX and if the sample size was ≥3. A standardized mean difference (SMD) ± standard error (95% confidence interval, CI) was calculated for at least one of the following outcomes in every study: post-void residual urine volume, reflex volume, bladder capacity, bladder compliance, catheterization frequency, and max flow rate. Results from all studies were then pooled using a random effects model. Treatment effect 52 Leveling the Playing Field - Making Sci Primary Care Accessible C. Mcmillan1, J. Lee1, J. Milligan1, T. Jeji2 1 , Centre for Family Medicine, Kitchener/ON/CANADA, 2, Ontario Neurotrauma Foundation, Toronto/ON/CANADA Background: Family Health Teams are positioned to make significant inroads in how primary care responds to individuals and their families with spinal cord injuries. Primary care delivered by a Family Health Team is the diagnosis, treatment and management of health problems by a inter disciplinary team of physician, nurse, social worker, pharmacist and occupational therapist. Access to these professionals is critical for the timely management of common secondary medical complications of SCI such as urinary tract infections, pressure sores and respiratory infections and to reduce unnecessary emergency room visits and acute care hospitalization (Jeji, 2010). However, this population has been traditionally marginalized by mainstream primary health care and routinely encounter substandard care due to accessibility issues, provider attitudinal barriers, lack of knowledge and training (Kroll, Beatty, Bingham, 2003).The absence of special equipment within physicians’ offices to accommodate SCI patients restricts the degree in which preventative services occur (Wolf-Branigin & LeRoy, 2004). Imaging equipment, adjustable exam tables, space clearances to accommodate wheelchairs and other accessibility concerns result in a diminished standard of care (Kaplan, 2006). Augmenting the structural challenges, many primary physicians are unlikely or even hesitant to have an SCI patient on their caseload, resulting in being unknowledgeable about SCI issues (Kaplan, 2006). The combination of objective (equipment) and subjective (knowledge & attitudinal) barriers has led to many patients accessing primary care in the emergency room. Methods: The Ontario Neurotrauma Foundation responded by initiating a number of projects that look at the delivery of services to those with a physical disability. The Centre of Family Medicine in Kitchener, Ontario was chosen based upon the establishment of a Mobility Clinic. Guided by a best practice model, the Clinic opened in 2010 staffed by an interdisciplinary team; physician, chiropractor, nurse, social worker and occupational therapist. A fully accessible clinic (hi-lo exam table, hoyer lift, wheelchair scale) allows many SCI patients the experience of receiving preventative health care for the first time. Knowledge barriers were addressed by upgrading skills through workshops and establishing an external mentoring relationship with a physiatrist. Attitudinal barriers are challenged by incorporating learners (family medicine residents, social work, nursing students) into the clinic. ONF also supported endeavours to make consumers their own advocates to ensure that as provider services improve, the ability of consumers to access and manage care will also improve. This endeavour took the form of a consumer driven advisory committee in addition to the Spinal Cord Injury Toolkit, a paper and electronic template that is part of the patient record and is done collaborately with the primary care physician. The Mobility Clinic at the Centre for Family Medicine represents a best practice model on several levels: partnering with external funding and knowledge experts, redefining clinical standards for SCI patients, fostering patient collaboration and piloting innovative methods to build capacity and offering preventative health care. The Mobility Clinic has made basic health care more equitable and accessible to individuals and families living with spinal cord injuries and other disabilities. Results: Ontario Neurotrauma Foundation, Toronto. P1-22 Factors Influencing Return to Community Living of Persons with SCI and their Family Members : For an Ecosystemic Perspective L. Beauregard , A. Guindon , L. Noreau , N. Boucher , H. Lefebvre3 1 , IRDPQ-CIRRIS, Québec/CANADA, 2, Centre for interdisciplinary research in rehabilitation and social integration (CIRRIS), Quebec/CANADA, 3, Universite de Montreal, Montreal/CANADA 1 1 2 1 Background: Returning to the community after intensive functional rehabilitation can be a challenge for people who sustained a traumatic spinal cord injury (SCI) and for their family members (1-4). In order to develop a better understanding of this important phase of re-integration to society, a prospective research study was conducted to assess the factors that affect community living. Methods: Semi-structured interviews were carried out with persons with SCI (n=35) and one of their family member (n=21), between 3 and 12 months post-rehabilitation (Time 1). Participants were met once again, a year after the first interview (Time 2) to determine whether or not their situation had changed. Interviews were recorded and transcribed for content analysis. Results: Through the content analysis, main concerns expressed by the persons with SCI and their family members were identified. People with SCI discussed themes such as adapting to their new situation, organizing personal care, driving and transportation, participating in leisure activities, etc. In total, 17 themes were identified. Family members talked about their relations to the person with SCI, feelings of overload, searching for information, etc. Nine themes were identified. For each of these themes, obstacles or facilitating elements were classified as pertaining to personal or environmental factors. This classification allowed to identify 7 main factors that influence the experience of returning to the community: 1) personal resources; 2) relationship between the person with SCI and the family member; 3) injury severity and secondary conditions; 4) cause of accident; 5) informal and 6) formal social support (services); and 7) architectural accessibility. For each of these factors, interventional targets and recommendations are proposed to enhance successful return to the community. These recommendations focus on all levels of intervention: micro-systems (ex. emotional and psychological support); meso-systems (ex. support from services and social support); macro-systems (ex. laws and regulations, raising awareness). The study emphasizes the importance of having an ecosystemic perspective in order to better understand the impacts interventions can have on the person and their family members in the phase of community reintegration. For a successful return to the community, interventions must focus on the individuals as well as on the immediate environment and society in general. References: · Anzai, K., et al., Factors influencing discharge location following high lesion spinal cord injury rehabilitation in British Colombia, Canada. Spinal Cord, 2006. 44: p. 11-18. · Boschen KA, et al., Community Reintegration Following Spinal Cord Injury., in Spinal Cord Injury Rehabilitation Evidence. Version 2.0. , Eng JJ, et al., Editors. 2008: Vancouver. p. 4.1-4.73. 53 · Charlifue, S. and K. Gerhart, Community integration in spinal cord injury of long duration. NeuroRehabilitation, 2004. 19(2): p. 91-101 · Lysack, C., et al., Environmental factors and their role in community integration after spinal cord injury. Canadian Journal of Occupational Therapy, 2007. 74(Special Issue): p. 243-254. P1-23 The Effects of the “Discovering the Power in Me” Program in Spinal Cord Injury A. Townson1, A. Chan1, K. Boschen2, C. Mcinnes1, B. Williams1, , University of British Columbia, Vancouver/ CANADA, 2, University of Toronto, Toronto/ON/CANADA Background: “Discovering the Power in Me” (DPM) is a 12unit clinical intervention developed by the Pacific Institute to improve the self-efficacy and self-esteem of individuals living with spinal cord injuries (SCI). It is based on cognitive psychology and social learning theory, which focusses on awareness of one’s thought processes in order to attain success in one’s life. Specifically, the central principle is that self-efficacy is the basis of well-being, human motivation, and accomplishments; one’s belief in his own efficacy is central in his ability to manage his functioning and use his physical and cognitive capabilities.(1) Such efficacy is influenced by one’s self-esteem, which is defined by the relationship between one’s positive and negative affect. Perceived self-efficacy corresponds accordingly with this affect, whereby a positive affect leads to an increased perceived self-efficacy and a negative affect leads to a decreased perceived self-efficacy. (2,3) Ultimately, the balance in one’s affect, and thus selfesteem, impacts the quality of one’s psychosocial functioning. (4) Methods: The DPM program was separately implemented and evaluated in two small pilot studies (n=19 in Vancouver and n=7 in Toronto). In Vancouver, individuals with SCI participated over two days, with pre-test, post-test, and 6-month follow-up. In Toronto, individuals with either SCI or acquired brain injury (ABI) but not both, participated in the program over three days and were followed again after 3 months in the pre-test, post-test, follow-up design. The Rosenberg Self-Esteem Scale (RSES) and the Life Satisfaction Questionnaire (LISAT-11) were used at both sites as measures of self-esteem and quality of life. The results from these independent sites were compared. Results: There were no statistically significant changes in the outcome measures in Vancouver, and the small number of participants in Toronto allowed for only a multiple n=1 design. However, an upward trend was seen on the RSES from both DPM sites, whereas minimal change was seen in the LISAT-11. 54 The mean change score trend in Vancouver for the RSES went from 27.6 to 34.5 to 33.9 from pre-workshop, to postworkshop, to 6 months post-workshop. In Toronto, individuals showed a peak RSES score immediately following the program completion, with corresponding 3 month follow-up values that either fell back to or remained elevated above baseline. Although the number of evaluation participants was not large and the research designs of the two individual studies differed somewhat, upward trends in self-esteem were determined from the similarly presented DPM programs. References: (1) Benight CC, Bandura A. Social cognitive theory of posttraumatic recovery: the role of perceived selfefficacy. Behav Res Ther 2004 Oct;42(10):1129-1148. (2) Rosenberg M. Society and the adolescent self-image (rev. ed.). Middletown, CT England: Wesleyan University Press; 1989. (3) Kavanagh DJ, Bower GH. Mood and self-efficacy: Impact of joy and sadness on perceived capabilities. Cognitive Therapy and Research 1985;9(5):507-525. (4) Bandura A, Caprara GV, Barbaranelli C, Gerbino M, Pastorelli C. Role of Affective Self-Regulatory Efficacy in Diverse Spheres of Psychosocial Functioning. Child Development 2003 00/00;74(3):769-82. Disclosure: Mr. Blake Williams is an unpaid consultant who provided the original design and development assistance for the DPM program to the Pacific Institute. He helped arrange the donation of curriculum materials from the Pacific Institute. P2-01 Icd-10 Coding Accuracy for Spinal Cord Injured Patients K. Tung, J. Shin, A. Kim, H. Ahn St. Michaels Hospital, Toronto/CANADA Background: Administrative databases such as the Canadian Institute of Health Information Discharge Abstract Database (DAD) are frequently used in health services research to assess regional variations in care and to assess morbidity and mortality of treatment. The purpose of this study was to determine the accuracy of diagnostic coding for surgical cases of spinal cord injury using ICD-10-CA codes in an administrative database, along with an optimal search strategy. Methods: All 1110 spinal surgery cases performed at St Michael’s Hospital during June, 2006 - June, 2008, an urban level 1 trauma center, were identified through a surgical registry database. Diagnosis obtained via health record review was used as the gold standard. We calculated for sensitivity, specificity, positive likelihood ratio, and positive predictive value of CIHI-DAD coding compared with the health record. Results: Of the 1110 spinal surgery cases, 82 cases were for acute traumatic spinal cord injuries. Fifteen different diagnostic codes for acute traumatic spinal cord injury were used. Combining all 15 codes using a Boolean “OR” function, sensitivity was determined to be 47.6%, specificity was 99.4%, positive predictive value was 86.6%, and positive likelihood ratio was 79.33. In contrast, within this same cohort of surgical cases, coding for myelopathy (cervical and thoracic) had a higher sensitivity of 81.6%. Interpretation Ascertainment of surgical cases of acute traumatic spinal cord injured patients from administrative databases using only ICD-10 diagnostic codes is poor. A potential source of error occurs due to missed coding of the cord injury in polytrauma patients with numerous injuries (many times over fifteen diagnoses in the clinical records). In contrast, surgical cases involving myelopathy, with typically a single diagnosis in the surgical records, are coded with significantly improved sensitivity compared to coding for acute spinal cord injured patients. international developments which, when taken together, suggest that there is a unique opportunity to be global leaders in clinical research registry development in spinal cord injury. Briefly, these developments are • the international spinal community has established the domains of disability in spinal cord injury and has expressed these in a manner consistent with the World Health Organization International Classification of Function (the Core Sets). • the Australian Spinal Cord Injury Register, a comprehensive registry of spinal cord injury across Australia could be readily extended to the Core Sets • the Rick Hansen Foundation is an international spinal charity that supports the established Canadian registry. The Core Sets are a mechanism for international collaboration and data aggregation. • a body of software engineering systems encompassed through eResearch now exists that will directly support this bid. References: None available P2-02 Development of an Integrated, Distributed Clinical Research Database for Spinal Cord Injury D.J. Berlowitz1, D.J. Brown2, P. Cameron3, M. Graco1, R. Sinnott4 1 , Institute for Breathing and Sleep, Melbourne/VIC/AUSTRALIA, 2 , Victorian Spinal Cord Service, Melbourne/VIC/AUSTRALIA, 3 , Department of Epidemiology and Preventative Medicine, Melbourne/VIC/AUSTRALIA, 4, eResearch, Melbourne/VIC/ AUSTRALIA Background: Spinal cord injury is a catastrophic injury that predominantly affects young men, most of whom then live for a further 50 years with substantial disability. Although thankfully the injury is relatively uncommon, the lifetime care costs are staggering. In 2010, Access Economics estimated the cost of spinal cord injury in Australia to be $2.0 billion annually, $5million per case of paraplegia (lifetime) and almost double that ($9.5 million) for quadriplegia. In fields of research such as spinal cord injury, where the number of patients is low, but the personal and societal impact is high, it is increasingly clear that integrated clinical research data are vital to enable discovery, facilitate investigation and to test treatments. So-called deep phenotyping of individuals with rare disorders is imperative to maximise opportunities for meaningful health economic evaluations, bio-bank linkage and to fulfil the promise of individualised medicine offered by the –omics revolution. This proposal will build such a resource. Methods: We will develop an integrated clinical research registry for traumatic spinal cord injury and the process of registry data collection will be embedded into routine clinical care. We will build on a number of recent local, national and Results: The primary data we require to measure the effect of novel therapeutic approaches and to improve patient outcomes in spinal cord injury are clinical. These phenotypic and outcome data are rich and complex but it is also the information that nurses, doctors and others accrue about people living with spinal cord injury as they pass through their care. This project will take these clinical process, map them to international standards and provide federated aggregation to facilitate research globally and to improve patient outcomes locally. This paper will report progress on our local implementation of this model. References: AccessEconomics. The economic cost of spinal cord injury and traumatic brain injury in Australia. 2009 June Biering-Sorensen F et al. International spinal cord injury data sets. Spinal Cord. 2006. 44(9):530-4. Norton L. Spinal Cord Injury, Australia 2007-08. Canberra: Australian Institute of Health and Welfare2010 November 2010 Contract No.: 52. P2-03 Effects of Seated Double-Poling Ergometer Training on Aerobic and Mechanical Power in Paraplegics A. Bjerkefors1, T. Lindberg2, C. Norrbrink3, K. Wahman4, A. Arndt2 1 , Human Locomotion Laboratory, School of Kinesiology, International Collaboration on Repair Discoveries, University of British Columbia, Vancouver/CANADA, 2, The Swedish School of Sport and Health Sciences, Stockholm, Sweden, Stockholm/SWEDEN, 3, Department of Clinical Sciences, 55 Karolinska Institute Danderyd Hospital, Stockholm/SWEDEN, 4 , Department of Neurobiology, Care Sciences and Society, Karolinska Institute, Rehab Station Stockholm/Spinalis, R & D unit, Stockholm, Sweden, Solna/SWEDEN Background: Post rehabilitation, the need for physical training still remains, to maintain the acquired abilities and avoid risks involved with a sedentary lifestyle (1). The purpose was to study the effects of seated double-poling ergometer training, performed by persons with spinal cord injury (SCI), on aerobic capacity and upper-body power output. Methods: Thirteen persons with SCI (8 M and 5 F, injury levels T5-L1), performed 50 min double-poling ergometer training three times per week during 10 weeks. Each session included warm-up, four interval sessions of 6 – 7 min, and cool-down. The intervals varied between 15 s and 3 min (70 – 100 % peak heart rate) with 15 s – 1 min rest. Before (test-retest) and after the training period, sub-maximal and maximal double-poling ergometer exercises were performed. Oxygen uptake was measured using the Douglas Bag system. Three-dimensional movements were recorded using an optoelectronic system and piezoelectric force sensors were used to register force in both poles for calculation of power output. Results: The average intra-class correlation coefficient for test-retest values were 0.81 (SD 0.11) for sub-maximal and 0.84 (0.11) for maximal test. Significant improvements after training were observed in oxygen uptake (22.7 %), ventilation (20.7 %) and blood lactate (22.0 %) during maximal exercises (Fig 1, Table 1). Mean power per stroke and peak pole force, calculated during the last 60 s, increased with 15.4 % and 23.7 %, respectively. At sub-maximal level, significantly lower values were observed in ventilation (-12.8 %) and blood lactate (-25.0 %) after the training period (Fig. 1, Table 1). Conclusion: Regular interval training on the SPDE was effective for individuals with SCI to improve aerobic capacity and upperbody power output. Furthermore, the training was safe and did not cause any overload symptoms (2). References: 1. Wahman K, Nash MS, Lewis JE, Seiger A, Levi R. Cardiovascular disease risk and the need for prevention after paraplegia determined by conventional multifactorial risk models: the Stockholm spinal cord injury study. J Rehabil Med 2011; 43 :237-242. 2. Norrbrink, C, Lindberg T, Wahman K, Bjerkefors A. Effects of an exercise programme on musculoskeletal and neuropathic pain after spinal cord injury – results from a seated double poling ergometer study (accepted for publication in Spinal Cord). 56 P2-04 Design and Progress of the Swiss Spinal Cord Injury Cohort Study (Swisci) M.W.G. Brinkhof, &. The Swisci Study Group Swiss Paraplegic Research, Nottwil/SWITZERLAND Background: Epidemiological research in spinal cord injury (SCI) will, similar to other rare or chronic conditions, greatly benefit from population-based study designs. Populationbased studies may function as registries that measure both incidence and prevalence; facilitate long-term monitoring and studying of the natural history of a condition; and play a role in the study of demographic and other risk factors. A registry may also provide the framework for representative and coordinated sampling of participants for specific studies (or nested projects) as to prevent mutual interference of outcomes and minimize the overall burden on individuals. We therefore recently initiated the Swiss Spinal Cord Injury cohort study (SwiSCI), which overall objective is advancing optimal functioning and quality of life of persons with SCI along the continuum of care and over the life span through comprehensive functioning and rehabilitation research1. Specific aims are assessing morbidity, mortality and longevity, with respect to specific risk factors as well as in comparison with the general population. Here we give an interim report on the progress of SwiSCI. Methods: SwiSCI is performed by the Swiss Paraplegic Research in collaboration with the four major specialized rehabilitation centers in Switzerland, including the Spinal Cord Injury Center of the Balgrist University Hospital, Zürich; Centre for Spinal Cord Injury and Severe Head Injury, REHAB Basel; Clinique Romande de Réadaptation, Sion; and the Swiss Paraplegic Centre, Nottwil. All four centers have specified regional catchment areas and admit both patients with traumatic and nontraumatic SCI. Other collaborating partners include the Swiss Paraplegic Association (SPV) and Parahelp, an organization providing home nursing services for the SCI community. Eligible participants in SwiSCI are Swiss residents with traumatic or non-traumatic SCI who are aged 16 or older, excluding SCI linked to progressive neurological disorders or end-of-life care. Identification of SCI cases is through three complementary pathways that, taken together, may eventually establish an ongoing population-based dataset. A unique list of persons with existing SCI is determined by combining personal information extracted from the medical records in the four SCI centers (Pathway 1; retrospective study, in Switzerland dating back to 1967) with existing membership and client lists of SPV and Parahelp. All persons identified living with SCI are invited to participate in a cross-sectional survey (Pathway 2) and asked for their consent for future follow-up. From mid 2012 onwards SwiSCI aims recruiting all Swiss persons with a newly diagnosed SCI admitted to one of the four study centers (Pathway 3). Results: The data collection in Pathway 1 and Pathway 2 is in progress. Based on the combined records of SPV, Parahelp and three study centers we have currently (11.12.2011) identified and contacted 3354 persons in Pathway 2. Pathway 1 data collection now covers 1990 to 2011; completion until 1967, in all centers and incorporating records from deceased persons, is foreseen by mid 2012. First results from the historical cohort will be presented at the Interdependence meeting. References: 1. Post MW et al Design of the Swiss Spinal Cord Injury Cohort Study. Am J Phys Med Rehab 2011;90 (Suppl 2):S5-16. P2-05 Best Practice Implementation in Inpatient Spinal Cord Rehabilitation – The Challenges of a Multi-Unit Site C. Scovil1, A. Burns1, H. Flett1, L. Nguyen1, D. Leber1, . Sci Kmn2 1 , Toronto Rehab, Lyndhurst Centre, Toronto/ON/CANADA, 2, SCI KMN, Toronto/ON/CANADA Background: Secondary health complications after Spinal Cord Injury (SCI) affect rehabilitation outcomes, and remain a risk for individuals living with SCI. Toronto Rehab is participating in a SCI Best Practices Implementation (BPI) initiative focusing on three secondary complications - pressure ulcers (PU), pain and bladder management. The SCI BPI includes 6 participating centres in Quebec, Ontario and Alberta, and is supported by implementation expertise from the National Implementation Research Network (NIRN). The objectives of the BPI project are to: • Promote adoption and utilization of best practices in SCI rehabilitation, and to increase implementation fluency for future BPI. • Establish collaborative knowledge mobilization networks (KMN) to identify and validate best practices. Methods: A Site Implementation Team (SIT) was formed, consisting of 2 Project Leads, Transformation Specialist and professionals with content expertise in the areas of PU prevention and patient and staff education. The SIT, supported by NIRN, is establishing the three key domains of drivers required to ensure effective implementation - leadership, organizational readiness and staff competency. A multi-site Delphi consensus process identified two PU best practices for initial implementation: • Conduct comprehensive assessment of risk factors • Provide structured PU prevention education Results: Challenges at our site include the size of our SCI program (three 18-bed units), leadership turnover and hospital merger, and the implementation of a new SCI-specific PU risk assessment scale (SCIPUS - Salzberg et al. 1996). Each unit has a distinct team of professionals, with individual team dynamics, strengths and challenges. Implementation strategies have been developed in the installation stage by the SIT, in consultation with NIRN and the SCI KMN: • Professionals from each unit were involved, and feedback gathered across units to ensure concerns were addressed. • Baseline data on PU prevalence and documentation compliance were collected across all three units. • Practice profiles were created that identify the critical components of the BPI process, and who is responsible for each component. This ensures consistent requirements across units, and creates clear expectations, even with changing leadership. • Strengths were highlighted, and specific challenges addressed for each unit individually. Information from the baseline PU prevalence and document compliance audit was used to encourage and motivate units to implement better practice. • Staff concerns with the existing risk assessment scale were acknowledged, resulting in implementation of a SCI-specific risk assessment scale. Staff view the SCIPUS as more appropriate to the patient population, which should improve buy-in and documentation compliance. • New forms and processes replaced existing ones to keep workload consistent and further increase front-line staff buy-in For the initial implementation phase, 1-2 ‘champions’ per unit will be selected and trained. They will identify implementation challenges on their unit, help with training, and provide on-site coaching. The BPI project provides a framework to effectively implement best practices for PU reduction, and lays the groundwork for more effective BPI in the future. References: Salzberg CA, Byrne DW, Cayten CG, van Niewerburgh P, Murphy JG, Viehbeck M (1996). A new pressure ulcer risk assessment scale for individuals with spinal cord injury. Am J Phys Med Rehabil 75:96-104. 57 P2-06 Systematic Review of Economic Studies in Spinal Cord Injury S.L. Hitzig1, B. Chan2, N. Mittmann3 1 , Toronto Rehabilitation Institute, Toronto/CANADA, 2, Leslie Dan Faculty of Pharmacy, Toronto/CANADA, 3, HOPE Research Centre, Toronto/ON/CANADA Background: It is estimated that there are 85,000 Canadians living with spinal cord injury (SCI) and approximately 3,700 new cases discharging from Canadian hospitals each year1. With SCI comes a sudden decrease in physical functioning and mobility. As a result, modifications to home and transportation are required to maintain a level of independence and productivity. A SCI also results in an increased risk for secondary medical complications such as urinary tract infection, pneumonia, pain and pressure ulcers resulting in higher rehospitalization rates and access to health care services2. Taken together, living with an SCI results in a significant economic burden to the individual, caregiver and the health care system. Though several studies have investigated economic burden in the SCI population, a review of the literature has not been conducted. Therefore this study will systematically review the medical and economic literature for economic studies related to SCI. Methods: A comprehensive literature review will be conducted using the MEDLINE®, EMBASE, HealthStar, CINAHL® and PubMed® databases using key words spinal cord injury, damage, contusion, laceration, trauma or fracture in combination with cost and cost analysis between 1980 and 2011. English language economic evaluation of spinal cord injury will be included. Conference abstracts will be excluded. A search of government and SCI advocacy group websites will also be conducted to retrieve any further reports on SCI costs. All resulting publication abstracts will be reviewed by two individuals. Articles agreed by both reviewers will be flagged and the full publication retrieved. The two reviewers will discuss any discrepancies between the articles identified for inclusion. Where there is a lack of consensus between the reviewers, a third individual will review the articles in question and make a final judgment. All publications eligible for the full analysis will be summarized for methods and results. Total costs reported will be converted and inflated to 2011 Canadian dollars. Results: A total of 67 articles were identified in all of the databases searched. All articles will be reviewed and screened for review inclusion. A preliminary review of the articles identified cost-of-illness studies as well as cost-effectiveness analyses from several countries. A preliminary search of additional sites from government and advocacy group websites has revealed cost studies from Australia and Canada. A more comprehensive search will determine which studies to include in the systematic review and whether additional cost studies exist. 58 References: 1. Farry A, Baxter D. The incidence and prevalence of spinal cord injury in canada: Overview and estimates based on current evidence 2010 Dec 2010. 2. Dryden DM, Saunders LD, Rowe BH, May LA, Yiannakoulias N, Svenson LW, et al. Utilization of health services following spinal cord injury: A 6-year follow-up study. Spinal Cord. 2004 Sep;42(9):513-25. P2-07 A National Approach to Implementing and Sustaining Evidence-Based Practices for Treatment and Prevention of Secondary Complications for Individuals with Spinal Cord Injuries R. Riopelle1, M. Duda2, J. Brown2, D. Wolfe3, J. Hsieh3, A. Dupuis4, A. Rasheed5, A. Burns6, H. Flett7, C. Joly8, J. Knox9, B. Stoesz10, V. Tam8, C. Truchon11, P. Wright9 1 , Ontario Neurotrauma Foundation/McGill University, Toronto/ ON/CANADA, 2, University North Carolina, Carroboro/NC/ UNITED STATES OF AMERICA, 3, Lawson Health Research Institute, London/ON/CANADA, 4, St. Joseph’s Health Care Parkwood, London/ON/CANADA, 5, Rick Hansen Institute, Vancouver/BC/CANADA, 6, Toronto Rehab, Lyndhurst Centre, Toronto/ON/CANADA, 7, Toronto Rehabilitation Institute, Toronto/ON/CANADA, 8, Institut de Réadaptation GingrasLindsay-de-Montréal, Montréal/CANADA, 9, Foothills Medical Centre, Calgary/AB/CANADA, 10, Glenrose Rehabilitation Hospital, Edmonton/AB/CANADA, 11, Institut de Réadaptation en Déficience Physique de Québec, Québec/QC/CANADA Background: The identification and use of evidence based interventions is critical to improving patient outcomes. Many times what is selected is not used by practitioners and/or; what is adopted as an intervention, is not used with fidelity with good outcomes for consumers; thus, the patient neither receives nor experiences the intended benefits of Evidence Based Practices(EBP). The purpose of the Spinal Cord Injuries Knowledge Mobilization Network(SCI-KMN) project was to address the critical need to identify EBPs to manage common secondary complications of SCI in three targeted domains of secondary complications: prevention and treatment of pressure ulcers; pain management; and bladder and bowel management. This inter-provincial project engaged six rehabilitation sites in three Canadian provinces to prevent and manage secondary complications in SCI patients. Methods: Six sites/(Centres of Excellence) across three Canadian Provinces,(Alberta, Ontario and Quebec). were selected based on their expertise and level of readiness for the development of implementation capacity. A systematic approach was used to identify and operationalize evidence- based practices one domain of secondary complications at a time (Delphi Process). Inter-provincial expertise and local (site level) stakeholders ranked priority best practices and use and implementation science informed lens to rate and rated elements such as fit, feasibility, sustainability and scalability. Consensus of the non-negotiable (expected) best-practices, performance measures for fidelity to the intervention, and fidelity to the process of implementation was achieved. Evidence-based Implementation practices via the use and assessment of active implementation frameworks (Fixsen_ et._al,_2005) were embedded throughout the entire process as the method to develop implementation capacity, influence system change and build sustainability. Results: The results of this work defines the replicable components necessary to operationalize best practices and use an evidence-based approach to ensure implementation. The first domain targeted was the prevention and treatment of pressure ulcers. An intensive six round Delphi process (Keeney_et_al._2001) with key stakeholders and experts, resulted in over 49 recommended practices for treatment and prevention of pressure ulcers which was then narrowed down to five critical practices. Once two practices were further identified as “Non-Negotiables” both Performance measures and Process fidelity measures were developed for use across all site. Through the support of the SCI KMN communities of practice, Implementation Teams utilized Active Implementation Science Frameworks to create operational and scalable mechanisms, processes and tools required to support and measure efficient and sustained implementation. This site level stagebased implementation capacity can be generalized to future evidence-based practices. These activities make important contributions toward building both fidelity-based intervention and fidelity-based implementation capacity by empowering organizations to achieve their goals to optimize service delivery for people with SCI, decrease burden and to improve their quality of life. References: Selected-References Fixsen, D. L., Naoom, S. F., Blase, K. A., Friedman, R. M. & Wallace, F. (2005). Implementation Research: A Synthesis of the Literature. Tampa, FL: University of South Florida, Louis de la Parte Florida Mental Health Institute, The National Implementation Research Network (FMHI Publication #231). Keeney S, Hasson F, McKenna HP. A critical review of the Delphi technique as a research methodology for nursing. Int J Nurs Studies 2001; 38:195-200. P2-08 First Year Anniversary of the Rick Hansen Spinal Cord Registry in Western Quebec: Facts and Figures at a Glance M. Grangeon1, I. Robidoux1, D. Gagnon1, K. Drouin2, S. Parent2, J. Mac-Thiong2 1 , Centre de recherche interdisciplinaire en réadaptation du Montréal métropolitain (CRIR) Institut de réadaptation Gingras-Lindsay-de-Montréal Laboratoire de pathokinésiologie, Montreal/QC/CANADA, 2, Centre de recherche, Hôpital du Sacré-Coeur de Montreal, Montreal, Canada, Montreal/QC/ CANADA Background: In 2011, it is estimated that there are over 86 000 people living with spinal cord injury (SCI) in Canada and over 4300 new SCI cases each year. Relevant information of population with SCI is important to optimise their rehabilitation. Since 2003, the Rick Hansen Spinal Cord Injury Registry (RHSCIR) tracks the experiences and outcomes of people with traumatic SCI during their journey through acute care, rehabilitation and community reintegration. To date no study has investigated these data through a statistical descriptive analysis. Thus the objective of our project was to provide a local method analysis of the RHSCIR data to draw a detailed picture of people who sustained a SCI in the western Quebec. Methods: At the end of 2010, 2300 participants from all Canada had consented to have their SCI-related data captured by the RHSCIR. The RHSCIR represents a working collaboration of 31 Canadian data collection sites. As of may 2011, the database contained information on 172 persons who sustained a traumatic SCI in Quebec. Our study describes 91 persons who sustained a traumatic SCI between May 2010 and May 2011 and who were admitted in the Centre d’Expertise pour les personnes Blessées Médullaires de l’Ouest du Québec (CEBMOQ) located in Montreal. The CEBMOQ includes the Hôpital du Sacré-Coeur de Montréal, the Institut de réadaption Gingras-Lindsay-de-Montréal and the Centre de réadaptation Lucie-Bruneau. Among the 91 persons, 72 gave their informed consent including 61 males and 11 females. All the statistics in this study are derived from this sample. Results: The mean age at injury was 47.3 years and most of injury occurred over 55 years. Overall 84.7% of SCI reported occurred among males. The majority of our sample (87.5%) was employed at the time of injury. Most (39.7%) were single but the majority (66.7%) was not living alone at the time of injury. Falls accounted for 48.6% of reported SCI followed by transport (30.6%), sport (8.3%) and assault (5.6%). The most frequent neurologic category was incomplete tetraplegia (32%), followed by complete paraplegia (29%), incomplete paraplegia (23%) and complete tetraplegia (16%). None of the participant experienced complete neurologic 59 recovery (ASIA E) upon hospital discharge. Over the last years, the percentage of persons with incomplete paraplegia has increased, while incomplete tetraplegia and complete paraplegia have decreased. The median day hospitalized in the acute care unit was 32 and 76 in the rehabilitation unit. At discharge from the system, 86% went to a private non institutional residence and 41.8% exhibited pain interference in daily life. The success of participation, the efficiency in the data collection and the synergy developed in each institution of the CEBMOQ demonstrated the feasibility of the project. Some clarifications in certain part of the questionnaire might avoid misinterpretation by participants and clinicians and might eliminate some confounding factors. Although some improvements in the database should be done to facilitate the data analysis (i.e. the data classification), the present approach gave interesting information for clinicians and researchers and should be extended to other RHSCIR local sites. References: Canadian Paraplegic Association. P2-09 Muscle Strength Changes Recorded Using Dynamometry During Robot Assisted Gait Training S. Galen1, C. Clarke1, A. Mclean2, D. Allan2, B. Conway1 1 , Bioengineering Unit, University of Strathclyde, Glasgow/ UNITED KINGDOM, 2, Queen Elizabeth National Spinal Injuries Unit, Glasgow/UNITED KINGDOM Background: Body Weight Supported Treadmill Training (BWSTT) is being increasingly used in the rehabilitation of incomplete spinal cord injured (ISCI) patients. The Lokomat (Hocoma) is a commercially available robot assisted BWSTT. Although previous studies have shown functional improvements in gait following Lokomat training in ISCI,1 the strength changes in lower limb muscles following BWSTT has received little attention. Objective: The aim of this study was to record changes in muscle strength in key lower limb muscle groups in acute and chronic ISCI patients under going daily Lokomat training. Methods: All procedures were approved by the ethics committee of the local health authority. Eighteen patients (acute = 13, chronic= 5) with ISCI participated in this study (Age range: 26-63 years, mean = 49.33 + 11.04 years). Each patient underwent a six week Lokomat training programme consisting of a daily target of 1 hour of BWSTT. Each patient also underwent routine functional and clinical assessments. In this study we used the Lokomat’s ability to measure isometric hip and knee joint moment in order to chart weekly changes in the maximal voluntary strength changes in the flexor and extensor muscles groups of those joints. Isometric measurements were made prior to the start of Lokomat 60 training and during the middle of each training week. Subjects were positioned in an upright standing posture within the Lokomat and instructed to make maximal efforts of flexor and extensor muscle groups of the hip and knee against a fixed orthosis. The moments generated were recorded by calibrated sensors within the orthosis. The best of three attempts of each exertion was taken as an estimate of the maximal voluntary strength. Rest periods between each exertion were given in order to avoid fatigue. Results: For all muscle groups tested there was a significant increase in the maximal strength recorded in the acute patient group (p<0.05). The time course of the changes reveals that in responding patients who demonstrate functional improvements in gait that there is clear evidence of strength increases in the hip and knee musculature within 3 weeks of training onset. This increase in strength continues to rise throughout the training programme but not in a simple linear fashion. In the chronic patient group strength changes were also seen but were of a lesser magnitude than those seen in the acute group. Conclusions: This study objectively measured the changes in muscle strength following robot assisted BWSTT. For patients receiving Lokomat rehabilitation the observation that increased hip and knee moments in responding patients can be seen by week 3 is indicative of treatment efficacy. However, in patients lacking a positive increase in strength by week 3 may denote that the patient is receiving no physiological benefit from the robot assisted BWSTT. Incorporating, regular dynamometry may therefore assist in revising treatment planning for patients who are considered for Lokomat or other forms of BWSTT. References: 1. Hornby TG, Zemon DH, Campbell D. Robotic-assisted, body-weight-supported treadmill training in individuals following motor incomplete spinal cord injury. Phys Ther. 2005 Jan;85(1):52-66. P2-10 The Development of an Outdoor Experiential Therapy (Oet) Cottage Program for Persons with Spinal Cord Injury C. Alton, N. Leong, N. Saunders, S.L. Hitzig University Health Network, Toronto Rehab, Toronto/ON/ CANADA Background: Although the rehabilitation team offers an inter-professional approach towards helping persons with spinal cord injury (SCI) achieve independence within their communities, the role of therapeutic recreation (TR) has been identified as being particularly important for achieving success in this domain (1,2). Unfortunately, the role of TR and its associated benefits following SCI is under-reported in the literature. The objective is to provide an overview of an outdoor experiential therapy (OET) intervention, the Spinal Cord Rehabilitation Program (SCRP) - Cottage Program, which is a 4-day/3-night trip to an accessible campground in Ontario where patients with SCI engage in a variety of outdoor activities (i.e., archery, handcycling, canoeing, sailing, etc.). Methods: The SCRP Cottage program affords patients an opportunity to experience a decrease in the environmental barriers that may have otherwise limited their ability to participate in a natural outdoor environment. The development and growth of the program have been enabled by: 1) conducting a benchmarking process to identify best practices on the implementation of the program; 2) adopting a theoretical model to underlie the accountability of the program; 3) engaging key stakeholders at the clinical, management, and community level (i.e., vendors); and 4) conducting evaluations on the outcomes of the program using a mixed-methods approach. Results: First round findings from the benchmarking process were of value and the program has advanced with involvement from research personnel and inter-disciplinary team members. As well, preliminary findings from the program evaluation yielded high rates of satisfaction and positive changes in well-being by participants. Given that people with SCI face life-long challenges to health, community participation and well-being, further attention is warranted on the importance of leisure towards contributing to success in these domains. TR interventions, such as the SCRP Cottage Program, are needed but can only grow if they are developed and evaluated at a higher standard. The outcomes illustrate a model of TR program development and evaluation, which can be used to inform the development of other SCI rehabilitation programs aimed at improving health and well-being. References: 1. Caldwell L, Dattilo J, Kleiber DA, Lee Y. Perceptions of therapeutic recreation among people with spinal cord injury. Ann Therap Rec 1994; 95: 13-6. 2. Dattilo J, Caldwell L, Lee Y, Kleiber DA. Returning to the community with spinal cord injury: Implications for therapeutic recreation specialists. Therap Rec J 1998; 32: 13-27. P2-11 Evaluating the Effects of an InterProfessional Therapeutic Cottage Program on Improving Well-being in Persons with Spinal Cord Injury A. Panjwani, C. Alton, N. Leong, N. Saunders, S.L. Hitzig University Health Network, Toronto Rehab, Toronto/ON/ CANADA Given that depression and altered self image can dramatically affect leisure participation [2], and that people who cope poorly post-injury are at risk of long-term difficulties, there is a need for interventions that address the psychological and environmental factors early post-injury in order to improve leisure outcomes. Hence, the purpose of the present study is to evaluate the therapeutic benefits of attending Toronto Rehab’s Spinal Cord Rehabilitation Program [SCRP] Cottage Program in patients with SCI. Methods: The SCRP Cottage is a unique outdoor experiential therapy intervention for Toronto Rehab patients with a SCI, which enables them to attend a 4-day/3 night visit to an accessible campsite supported by an inter-professional team. The program allows patients to engage in a variety of land and water-based recreation activities (canoeing, handcycling, etc.). Program evaluation data was collected in 2010 and 2011 and was pooled for analysis. A between subject pre-posttest design was employed where cottage participants (n = 26) and a comparison group of non-participants (n = 17) completed surveys on self-esteem (Rosenberg Self-Esteem Scale), mood (Positive Affect and Negative Affect Scale), and self-efficacy (Moorong Self-Efficacy Scale). Results: Repeated measures ANOVA indicated that for patients who attended the cottage program, positive affect increased (T1: M = 38.2, T2: M = 44.0) over time (p< 0.05) while remaining constant for non-participants (T1: M = 36.0, T2: M = 37.0). For both groups, self-esteem increased over time (cottage T1: M = 22.2; T2: M = 26.0; non-participants T1: M = 21.0, T2: M = 22.5) while negative affect decreased (p < 0.05; cottage T1: M = 17.9; T2: M = 14.6; nonparticipants T1: M = 19.4, T2: M = 18.6). The interaction between time and group for self-efficacy was barely nonsignificant (p =.05), suggesting there was a trend for increased self-efficacy over time in cottage participants (T1: M = 85.0, T2: M = 89.3) compared to non-participants (T1: M = 80.0, T2: M = 78.0). Attending the SCRP Cottage program yielded gains in positive mood in participants with SCI compared to non-participants. As well, gains in self-esteem and decreases in negative mood were demonstrated in both groups. The findings in the cottage participants are likely attributed to their attending the program while the gains displayed by the controls could be due to a variety of reasons (e.g., neurological recovery during rehabilitation, other positive life events). Overall, the findings highlight that attending a therapeutic cottage program improves well-being, which may hold longterm benefits for a healthy active lifestyle post-SCI. References: 1. Vissers M, et al. Barriers to and facilitators of everyday physical activity in persons with a spinal cord injury after discharge from the rehabilitation centre. J Rehabil Med. 2008; 40: 461-7. 2. Carpenter C. The experience of spinal cord injury: The individual’s perspective – Implications for rehabilitation practice. Phys Ther. 1994; 74: 614-29. Background: After sustaining a spinal cord injury (SCI), opportunities for participating in outdoor recreation leisure pursuits are reduced due to physical barriers (e.g., lack of equipment) and emotional issues that may arise post-injury [1]. 61 P2-12 P2-13 Cardiovascular Control in the Acute Period After Spinal Cord Injury: A Case Series Systems Thinking Perspectives in Spinal Cord Injury Research and Practice J. Inskip1, M. Mcgrath1, B.K. Kwon2, V. Claydon3 1 , Simon Fraser University, Burnaby/CANADA, 2, Combined Neurosurgical and Orthopaedic Spine Program (CNOSP), Department of Orthopaedics, University of British Columbia, Vancouver/BC/CANADA, 3, ICORD, Vancouver/BC/CANADA A. Jetha, Y. Hamdani Dalla Lana School of Public Health, University of Toronto, Toronto/CANADA Background: In addition to the motor and sensory deficits following spinal cord injury (SCI), SCI can disrupt autonomic pathways that travel in the spinal cord, resulting in a range of cardiovascular dysfunctions. The acute development and evolution of these complications remains poorly understood. Ultimately, to develop treatments to improve cardiovascular function, we must first understand the typical progression of these dysfunctions. Here we sought to evaluate cardiovascular function in the acute time period after SCI. Methods: Cardiovascular parameters were measured at multiple time points in the first six months post-injury. Using non-invasive equipment, resting supine beat-to-beat blood pressure and 3-lead electrocardiography were recorded over a 15 minute period at 2-10 days, 2-4 weeks, 2-3 months and 6 months post injury, in three male subjects with SCI. Individuals also completed a questionnaire developed in our laboratory evaluating symptoms of cardiovascular dysfunction after SCI. Autonomic function was quantified using spectral analyses of heart rate and blood pressure variability. Results: The total variability in heart rate and blood pressure changed with time after injury; two subjects showed increased blood pressure variability with time after injury, while one subject showed a decrease. Heart rate variability showed less clear effects over time. Particular frequency domains that are related to breathing frequency, baroreflex sensitivity and sympathetic activity showed pronounced differences over the four recording sessions, suggesting that there may be changes occurring in cardiovascular autonomic control during this acute post-injury period. The early period after SCI appears to be a time when the cardiovascular system is changing significantly. Therefore, we should think carefully about when we assess the cardiovascular system following SCI. This case series shows that spectral analyses of blood pressure and heart rate variability are sensitive to changes in the cardiovascular system over time. This technique may allow us to measure cardiovascular control and the relative contributions of sympathetic and parasympathetic activity and how they change with time after injury. References: No references 62 Background: Spinal cord injury (SCI) is a highly complex health condition. From a public health perspective, the performance of health-enhancing behaviours (e.g. selfmanagement or physical activity) by people living with SCI can be influenced by a diversity of factors including, but not limited to health and disability (e.g. level and completeness of injury and presence and severity of secondary health conditions), personal (e.g. age, gender and socioeconomic status) and environmental (e.g. aspects of the built, physical and social environments) factors. Although existing research has elaborated on these different factors, little is known about how they interact and contribute to both anticipated and unanticipated outcomes. Systems thinking, a perspective which has grown from business and engineering sciences, provides an understanding of how factors interact and influence one another within a whole and produce patterns of behaviours. Methods: This presentation will introduce systems thinking and provide a discourse on complexity as applied to SCI health promotion research and practice. Systems dynamics methodology which involves designing a series of causal loop diagrams will also be described as one systems method for conceptualizing SCI research and identifying key areas of intervention (i.e. leverage points). Results: By understanding complex interactions and patterns of relationships between factors, practitioners and policy makers will be better able to determine key areas of health promotion intervention, the impact of these interventions on the system and the potential intended and unintended consequences of change. References: Hamdani, Y., Jetha, A., Norman, C.D. (2011). Systems thinking perspectives applies to healthcare transition for youth with disabilities: a paradigm shift for practice, policy and research. Child: care, health & development, 37 (6) 806814. P2-14 Examining Workplace Activity Limitations Among Young Adults Living with Spinal Cord Injuries: A Pilot Study A. Jetha1, B.C. Craven2, E. Badley1, D. Beaton3, M. Gignac1 1 , Dalla Lana School of Public Health, University of Toronto, Toronto/ON/CANADA, 2, Toronto Rehabilitation Institute, Spinal Cord Injury Rehabilitation Program, Toronto/ON/CANADA, 3, St. Michaels Hospital, Mobility Program, Clinical Research Unit, Toronto/ON/CANADA Background: Research suggests that people living with spinal cord injury (SCI) are less likely to be employed compared to their able-bodied peers. However, few studies have examined specific workplace activity limitations facing people living with SCI and potential differences from other chronic health conditions. As part of a larger study examining the employment participation of young adults living with chronic physically disabling health conditions, this pilot study describes difficulties with work participation experienced by a sample of young adults living with SCI. In addition, it examines difficulties compared to a larger sample of young adults living with juvenile arthritis (JA) and systemic lupus erythematosus (SLE). Methods: Eligible participants ages 18 to 30 years are currently being recruited from clinics and community organizations in Ontario, Saskatchewan and British Columbia. Participants complete an online questionnaire asking about demographics (e.g., age, gender, education), health (e.g., injury-level and completeness, fatigue, pain, secondary health conditions) and employment, including questions about employment status and career satisfaction (5-item Career Satisfaction Scale: 1 = not at all satisfied; 5 = extremely satisfied). Difficulties with work participation were assessed using the Workplace Activities Limitations Scale (WALS). WALS gauges problems with lower mobility (e.g., wheeling for long periods, sitting, standing), upper mobility (e.g., reaching and grasping), and job demands (e.g. the pace or schedule of work). Items are responded to on a 4-point scale (1 = no difficulty; 4 = unable to do). Descriptive and comparative statistics (i.e. Analysis of Variance) were conducted. Results: To date, 102 young adults living with SCI (n = 7), JA (n = 35) and SLE (n = 60) have completed the questionnaire (mean age = 23.8, SD =3.4). 57% of the sample with SCI were employed compared to 60.3% with JA and SLE. Overall, young adults with SCI reported moderate to low difficulties with workplace activities (mean WALS score = 1.9 (SD = .48)), which was not significantly different from young adults with JA (mean WALS score = 1.5 (SD = .50)) and SLE (mean WALS score = 1.6 (SD = .52)). Examining individual WALS items, respondents with SCI reported significantly greater difficulties commuting to and from work (1.8 vs. 1.3), getting around the workplace (1.8 vs. 1.3) and reaching (2.3 vs. 1.3) than respondents with JA and SLE (p < .05). There were no significant differences reported with job demands, including concentrating on work (1.8 vs. 1.6) or the scheduling and pace of work. However, participants with SCI were significantly less satisfied with their career progress compared to participants with JA and SLE (2.3 vs. 3.5; p < .01). Discussion: Although the data are preliminary, they highlight the importance of examining, not only the overall level of workplace activity limitations across different chronic conditions, but also specific areas that may be problematic (e.g., mobility versus the pace of work). The data also suggest the need to look at links between workplace activity limitations and career satisfaction. Interventions to improve employment participation should include strategies to help young adults deal with specific workplace problems, including environmental barriers. References: 1. Gignac MAM. Arthritis and employment: An examination of behavioral coping efforts to manage workplace activity limitations. Arthritis & Rheumatology. 2005;53(3):328336. P2-15 Economics of Traumatic Spinal Cord Injury in Canada H. Krueger1, C. Rivers2, V. Noonan3, L. Trenaman1, P. Joshi2, M. Dvorak4 1 , H. Krueger & Associates Inc., Delta/CANADA, 2, Rick Hansen Institute, Vancouver/CANADA, 3, University of British Columbia, Vancouver/BC/CANADA, 4, Rick Hansen Institute, Vancouver/BC/CANADA Background: An estimated 1,400 Canadians survive a tSCI each year. These survivors suffer a high rate of preventable secondary complications. We aim to determine the economic burden of traumatic spinal cord injury (tSCI) in Canada, and to evaluate the potential costs avoided by reducing the incidence of secondary complications, particularly pressure ulcers (PUs) and urinary tract infections (UTIs). Methods: This health economics study uses available information in the academic and grey literature on the incidence, prevalence, resource use, survival and quality of life of individuals with tSCI to estimate the lifetime economic burden of a tSCI and the potential costs avoided if the incidence of specific types of secondary complications (such as PUs and UTIs) can be reduced. Both direct and indirect costs are calculated in estimating the lifetime economic burden of a tSCI while the focus is on direct costs avoided by reducing the incidence of secondary complications. Preliminary results are presented in this abstract. 63 Results: The total lifetime economic burden of a tSCI that occurs at age 35 is between $1.47 and $3.03 million dollars depending on type/severity of injury. Direct costs consist of approximately 50% of this economic burden. The total annual economic burden of tSCI in Canada is estimated at $2.67 billion. If a modest 20% reduction of PU or UTI incidence was achieved in the Canadian tSCI population, $71.08 and $12.21 million in direct care costs, respectively, could be avoided annually in Canada. tSCI is a huge economic burden to healthcare systems. Advances in the prevention of secondary complications can greatly reduce both the burden on tSCI patients and provide a substantial reduction in economic burden. These advances may also be applied to other relevant patient groups, leading to even further patient and economic benefit. References: No references added at this time. P2-16 Non-Neurological Complication Rate Following Surgical Stabilization of Vertebral Fracture with Neurological Impairment. Does Surgical Timing Matter? E. Bourassa-Moreau1, S. Parent2, C. Thompson3, J. MacThiong1 1 , Université de Montréal, Montréal/CANADA, 2, Hôpital du Sacré-Coeur, Montreal/CANADA, 3, Hôpital du Sacré-Coeur de Montréal, Montréal/CANADA Background: Optimal timing of surgery after vertebral fractureluxation is one of the most controversial subject in spine surgery. We wanted to determine if early surgical stabilization decreases non-neurological complications during acute phase hospitalisation in vertebral trauma with neurological impairment. Methods: We studied a retrospective cohort comprising 314 patients with vertebral fracture or dislocation with neurological impairment. For each patient, post-operative complications that occurred during the acute hospitalisation phase (pulmonary embolus, deep venous thrombosis, pneumonia, urinary tract infection, pressure ulcers and other complications) were collected. We examined the occurrence of non-neurological complications during different intervals pertaining to the timing of the surgical intervention with respect to the spine trauma (<24h, <48h, <72h and >72h). Logistic regression analysis model was adjusted for covariables such as age, sex, trauma mechanism, vertebral level, completeness of injury, Injury Severity Score (ISS), Charlson Comorbidity Index (CCI) and Surgery Invasiveness (SI). 64 Results: The rate of occurence of non-surgical complications, except for urinary tract infection was significantly higher when surgery was performed more than 72h after the vetebral trauma. When controlling for confounding variables, surgical decompression performed within 72h after post-injury was associated with lower rates of non-neurological complications. Higher complication rates were associated to more severe trauma (ISS), greater number of comorbidities (CCI), age, completeness of injury and tetraplegia. In order to decrease the rate of complications, the authors recommend performing spinal decompression/stabilization as soon as the patients are stable enough to undergo surgery within the first 72 h after the trauma. References: Carreon LY, Dimar JR. Early versus Late Stabilization of Spine Injuries: A Systematic Review. Spine (Phila Pa 1976). 2011 Jan 25. Fehlings MG, Rabin D, Sears W, Cadotte DW, Aarabi B. Current practice in the timing of surgical intervention in spinal cord injury. Spine (Phila Pa 1976). 2010 Oct 1;35(21 Suppl):S166-73. Bellabarba C, Fisher C, Chapman JR, Dettori JR, Norvell DC. Does early fracture fixation of thoracolumbar spine fractures decrease morbidity or mortality? Spine (Phila Pa 1976). 2010 Apr 20;35(9 Suppl):S138-45. Kerwin AJ, Frykberg ER, Schinco MA, Griffen MM, Murphy T, Tepas JJ. The effect of early spine fixation on non-neurologic outcome. J Trauma. 2005 Jan;58(1):15-21. Croce MA, Bee TK, Pritchard E, Miller PR, Fabian TC. Does optimal timing for spine fracture fixation exist? Ann Surg. 2001 Jun;233(6):851-8. Vaccaro AR, Daugherty RJ, Sheehan TP, Dante SJ, Cotler JM, Balderston RA, Herbison GJ, Northrup BE. Neurologic outcome of early versus late surgery for cervical spinal cord injury. Spine (Phila Pa 1976). 1997 Nov 15;22(22):2609-13. P2-17 Patient-Centred Care: Using Operations Research Techniques to Improve Care for Persons with Spinal Cord Injury V. Noonan1, D. Atkins1, A. Santos1, R. Lewis1, L. Soril2, M.G. Fehlings3, A. Singh3, M. Dvorak2 1 , University of British Columbia, Vancouver/BC/CANADA, 2, Rick Hansen Institute, Vancouver/CANADA, 3, University of Toronto, Toronto/ON/CANADA Background: The provision of care is heavily influenced by both clinical decision-making and system (administrative) processes. Clinical care directly impacts patient outcomes. System processes are influenced by resources, organizational structures, geography, patient demographics and staffing and have direct effects on length of stay, time to surgery, and rehabilitation intensity, which in turn also affect patient outcomes. System and clinical processes are completely integrated; in the case of patients with traumatic spinal cord injury (SCI), who receive care in many different units and require multiple interventions over significant periods of time, the integration is particularly complex. Similar problems in business and engineering have been addressed using the techniques of Operations Research (OR); these techniques may offer a unique solution to the complexities encountered in SCI care. The objective of the Access to Care and Timing project is to model the care continuum for persons with traumatic SCI in Canada using OR methods. Specifically, this project will assess whether access to specialized services and the timing of the interventions affect system and patient outcomes; these outcomes will be evaluated using a simulation model. Methods: A partnership was developed between the Rick Hansen Institute and the Centre for Operations Excellence at UBC. A high-level overview (level 1 maps) of SCI care in Canada was described for SCI centres participating in the Rick Hansen SCI Registry (RHSCIR). Detailed process maps, along with data from RHSCIR, evidence from the literature and expert opinion were used to develop a discrete event simulation model (DES) of the traumatic SCI continuum of care. A second health progression model was built to examine the long-term impacts (recurrence of complications, costs, quality-adjusted life years, mortality) once persons with SCI return into the community. Results: To date, level 1 maps have been developed for 25 SCI centres in 12 cities. The general DES model is being tailored to SCI centres in four cities which have completed the detailed process mapping. Validation of the models is ongoing. Results from the models have been used to determine the direct and indirect effects of hypothetically implementing new initiatives (e.g. pressure ulcer guidelines), as well as to examine which policy initiatives would facilitate early access to surgery in two Canadian centres. Additional benefits of conducting the process mapping include creating dialogue among health care providers both along the continuum of care and across Canada. With an ever increasing demand on the health care system there is a need to critically evaluate the processes of care to determine the attributes of a system that provides cost effective quality care. The use of OR methods has enabled SCI care to be examined along the continuum and identify unique differences in care delivery across Canada. Results from the ACT models provide the evidence required to support clinical decision-making and inform standards of care. References: Not applicable P2-18 Does Autonomic Dysfunction Play a Role in the Development of Cardiovascular Disease After Spinal Cord Injury? R. Ravensbergen1, I. Sahota2, S. Lear2, A. Krassioukov3, V. Claydon2 1 , ICORD, Vancouver/CANADA, 2, Simon Fraser University, Burnaby/CANADA, 3, University of British Columbia - Physical Medicine and Rehabilitation, Vancouver/CANADA Background: Cardiovascular disease after spinal cord injury (SCI) is the leading cause of morbidity and mortality in this population. The mechanisms underlying this increased risk are still unclear. Until now lifestyle changes after SCI have been thought to be the most important factor, causing negative changes in metabolic state (e.g. cholesterol levels) and body composition (e.g. fat percentage), which are related to a higher risk of cardiovascular disease. However, we propose that injury to spinal autonomic pathways plays an important role. It is possible that cardiovascular disease risk is increased as a direct effect of damage to these pathways or indirectly as a consequence of decreased exercise intolerance. Therefore, we aimed to compare risk factors for cardiovascular disease between individuals with an autonomically complete SCI, autonomically incomplete SCI and able-bodied controls. Methods: The spinal cord injury group was subdivided by completeness of injury to cardiovascular autonomic pathways. Individuals were determined autonomically complete based on level of injury (above T5), low plasma noradrenaline level, low power of low frequency (LF) oscillations in systolic arterial pressure (SAP)1 and having symptoms or signs of orthostatic hypotension and or autonomic dysreflexia. Risk assessment parameters for cardiovascular disease were compared between the groups: glucose tolerance, fasting glucose and insulin, fasting cholesterol and triglycerides as well as measures of obesity (fat mass, abdominal fat mass). Physical activity was determined using the Physical Activity Scale for Individuals with Physical Disabilities2 (PASIPD). Measurements were conducted in 14 able-bodied controls, 11 individuals with autonomically complete SCI and 12 individuals with autonomically incomplete SCI. Results: Risk factors related to glucose handling were impaired only in the autonomically complete SCI group. Lipid profiles were impaired in both SCI groups; HDL cholesterol was lower, while LDL cholesterol was not different from the able-bodied controls. Physical activity scores were similar in the two groups with SCI. These preliminary data are compatible with an independent relationship between autonomic dysfunction after SCI and adverse cardiovascular risk profiles, such as impaired glucose handling. Impairments in lipid profiles did not seem to be affected by autonomic dysfunction. These findings support the 65 need to target treatment towards autonomic dysfunction after SCI, in addition to lifestyle modification, in order to reduce morbidity and mortality due to cardiovascular disease. References: 1. Kleiger RE et al. Noninvasive Electrocardiology 2005 (10) 88-101 2. Washburn RA et al. Archives of Physical Medicine and Rehabilitation 2002 (83) 193-200 P2-19 Access to Primary Care for Persons with SCI: A Health Service Delivery Study J. Richardson1, L. Macrae2, S. Wojkowski1, A. Moore3, D. Oliver3, D. Price1, K. Leblanc2, T. Czajka2, S. Sinclair1, P. Athanasopolous4, T. Jeji5 1 , McMaster University, Hamilton/ON/CANADA, 2, Hamilton Health Sciences, Hamilton/ON/CANADA, 3, McMaster Family Health Team, Hamilton/ON/CANADA, 4, Canadian Paraplegic Association Ontario, Toronto/ON/CANADA, 5, Ontario Neurotrauma Foundation, Toronto/ON/CANADA Background: Individuals with spinal cord injury (SCI) have difficulty accessing primary care services, specifically services provided within family practices.1 SCI is a chronic condition that requires ongoing management, prevention strategies and interactions with health care professionals. This demonstration project will develop and implement a model of care that will formalise a health services relationship between a hospitalbased spinal cord injury specialist team at Hamilton Health Sciences and primary care practice sites of two Hamilton Family Health Teams (FHTs). Capacity building will occur within the FHTs by increasing the knowledge and competency of primary care teams to provide services to persons with SCI. Aspects of the Expanded Chronic Care model which is being adopted in Ontario as a framework to manage chronic conditions will be addressed by this project. The model will include a self-management component in which patients will learn the skills to manage their condition. Purpose The purpose of this project is to improve the management of care for patients with SCI in a primary healthcare setting. Methods: A partnership will be developed between two Hamilton Family Health Teams, the spinal injury team at Hamilton Health Sciences, and the Canadian Paraplegic Association Ontario to facilitate access to timely and informed primary care for individuals with SCI. This partnership will facilitate the care of patients with SCI in a primary care setting and will enable knowledge transfer and capacity building between the specialized spine consultation team and the physicians and patient care providers on the FHTs. It will provide benefits to the following stakeholders: Patients without a FP will have increased access to primary care. This model will enhance the health of patients with SCI by increasing the 66 continuity of care between primary care and specialized SCI services. Physicians and patient care providers will receive increased support in practices within the FHTs through linkages to a team of specialists in SCI at Hamilton Health Sciences (HHS) to support them in the care of these patients. The Spinal Cord Injury Specialist Team will benefit by providing support which will enable the SCI patient population to gain access to care at the most efficient point of entry to the health care system. This approach to care is likely to result in fewer hospital admissions and ER visits and patients are more likely to have health complaints appropriate to primary care managed at this level of the healthcare system. Results: Sustainability This model of care will be tested within the Hamilton region, however we envision it is sustainable in other healthcare settings where there are similar resources. We anticipate that it will be transferrable to other FHTs within the region and the province where linkages can be made between a SCI Specialist Team and primary care providers. Acknowledgement: This project funded by the Ontario Neurotrauma Foundation. References: 1. McColl, M., et al., Physician Experiences Providing Primary Care to People with Disabilities. Healthcare Policy, 2008. 4: p. e129-e147. P2-21 Use of the Spine Adverse Events Severity (Saves) Instrument for Traumatic Spinal Cord Injury J. Street1, V. Noonan2, C. Fisher3, A. Cheung2, B. Sun2, M. Dvorak1 1 , Vancouver General Hospital, Vancouver/BC/CANADA, 2, Rick Hansen Institute, Vancouver/BC/CANADA, 3, Vancouver General Hospital, Vancouver/CANADA Background: Adverse events are common during acute care in patients with traumatic spinal cord injury (tSCI). International Classification of Diseases (ICD) codes are used in hospital administrative databases to manage health-related information. Administrative data is often used to report adverse events; however, this data may not reflect patient complexity and outcome. The Spine Adverse Events Severity (SAVES) instrument has been validated for adverse event recording in the spine. The objective of this study was to determine if SAVES was superior to ICD-10 codes in measuring adverse events in patients with tSCI. Methods: Patients discharged between 2006 and 2010 were identified from our prospective registry. Two cohorts were created based on the method used to record adverse events; Cohort 1 used ICD-10 codes from the hospital Discharge Abstract Database and Cohort 2 used SAVES data. The ICD-10 codes were mapped to adverse events in SAVES. The five most common adverse events were examined: neuropathic pain, urinary tract infections (UTI), pneumonia, pressure ulcers and delirium. There were 212 patients in Cohort 1 and 173 patients in Cohort 2. Analyses were adjusted to account for the different sample sizes and the two cohorts were comparable based on age, gender, mechanism of injury and motor score. Results: There was an 18% increase in the number of patients diagnosed as having one or more adverse events using SAVES (76%) compared to ICD-10 codes (58%). The number of adverse events recorded per person was doubled using SAVES (1.3 versus 2.7). SAVES reported greater incidence of neuropathic pain (x32), UTI (x1.4), pneumonia (x1.2), pressure ulcers (x2.9) and delirium (x1.2). The number of intra-operative adverse events identified was 2.3 times greater using SAVES (7.5% versus 17.3%). The implementation of the SAVES system for patients with tSCI captured more patients experiencing adverse events and more adverse events per person compared to using ICD-10 codes from an administrative database. This study demonstrates the utility of prospectively collecting data on adverse events using validated tools. References: Not applicable P2-22 Long-Term Follow-Up of Bladder Function in Patients with Spinal Cord Injury J. Wöllner, M. Walter, F. Gregorini, D. Birnböck, U. Mehnert, T. Kessler Neuro-Urology, Spinal Cord Injury Center, Balgrist University Hospital, University of Zurich, Switzerland, Zurich/ SWITZERLAND Background: Patients with spinal cord injury (SCI) often suffer from bladder dysfunction according to the completeness and the level of the lesion (1). Neurogenic detrusor overactivity (NDO) frequently combined with detrusor sphincter dyssynergia (DSD) is a common condition after suprasacral injuries. The upper urinary tract is at risk due to high intravesical pressure, which often causes vesico-ureteral reflux (VUR), when adequate treatment is postponed or have never been introduced at all. Quality of life and life expectancy are constantly increasing due to the improvement of therapeutic options for this group of patients over the last decades. We assessed the long-term bladder function in patients after SCI. Methods: An evaluation of 56 consecutive patients (12 females, 44 males) suffering from neurogenic bladder dysfunction due to SCI for at least five years with regular follow-up and a current urodynamic examination was performed between January and September 2010. Results: Our collective (mean age at SCI 31±13 years; mean duration of urodynamic evaluation 15 years, range 5-42) contained 51 patients suffering from a traumatic onset, while 5 had other lesions (toxic, inflammatory). The level of lesion was divided in cervical (14/56), thoracic (32/56), lumbar (8/56), and sacral (2/56). Clean intermittent catheterization (CIC) was the primary way of bladder emptying (29/56), whereas 7 had an indwelling catheter and 9 voided spontaneously. Urinary incontinence was present in 34% (19/56). The favorite medical treatment was oxybutynin (15/56). Low grade VUR (maximum grade 2) was detected unilaterally in 7 patients and bilateral in one patient. Mean compliance was 65 (SD±213) mL/cmH20 and mean maximum cystometric capacity 447 (SD±136) mL. NDO was observed in 29 patients (14 were without treatment, the remaining were mostly under oxybutynin), while 16 of them were incontinent (mean detrusor leak point pressure of 42±29 cmH20). Most of our regularly followed patients suffering from neurogenic bladder dysfunction due to SCI for at least 5 years had normal cystometric capacity and compliance. VUR was quite rare and low grade. Thus, to allow an individual bladder management we strongly recommend a regular follow-up with an urodynamic evaluation. References: (1) Stöhrer M, Blok B, Castro-Diaz D, ChartierKastler E, Del Popolo G, Kramer G, Pannek J, Radziszewski P, Wyndaele JJ. EAU guidelines on neurogenic lower urinary tract dysfunction. Eur Urol 2009; 56:81-8. P2-23 Does Bacteriuria Matter in Patients with Neurogenic Lower Urinary Tract Dysfunction? M. Walter, J. Wöllner, F. Gregorini, D. Birnböck, M. Kozomara, U. Mehnert, T. Kessler Neuro-Urology, Spinal Cord Injury Center, Balgrist University Hospital, University of Zurich, Switzerland, Zurich/ SWITZERLAND Background: The function and integrity of the lower urinary tract is often affected by neurologic diseases (1). The influence of recurrent urinary tract infections on the quality of life is significant and still a challenging task in neuro-urology. Therefore, we investigated in patients with neurogenic lower urinary tract dysfunction (LUTD) the incidence of symptomatic urinary tract infections (UTI) and asymptomatic bacteriuria to find potential risk factors. Methods: An evaluation of 185 consecutive patients with neurogenic LUTD undergoing urodynamic investigation was performed prospectively. Urine samples for urine culture were obtained by sterile catheterization prior to the examination. At this moment, none of the patients complained about any symptoms of UTI. The occurrence of UTI was captured for each patient. Data were normally distributed and the values are 67 presented as mean ± standard deviation. Uni- and multivariate analyses (including gender, age, mode of bladder emptying, video-urodynamic parameters as well as type and duration of the neurologic disorder) were performed to detect predictors for asymptomatic bacteriuria and/or symptomatic UTI. Results: Spinal cord injury (n=120), multiple sclerosis (n=23), spina bifida (n=2), Parkinson’s disease (n=3), and others (n=37) were found to be the underlying neurologic disorders (mean duration 11±15 years) in our collective of 185 patients (mean age 49±16 years). Aseptic intermittent self-catheterization (n=71) and spontaneous voiding (n=51) were the most common ways for bladder emptying. Evaluation of the urine culture revealed a bacterial growth >105/mL in 76 (41%) patients and a bacterial growth <104/mL in 39 (21%) patients, while 70 (38%) patients had no bacterial growth at all. Although E.coli (17.8%) and Klebsiella pneumoniae (9.7%) were the predominant bacteria, all patients were asymptomatic. No predicting factors were found in uni- and multivariate analyses for either asymptomatic bacteriuria or symptomatic urinary tract infection (mean rate 1.0±1.9 per year during follow-up). Since the incidence of symptomatic UTI was only about 1 per year, whereas more than 60% of our patients had a significant bacterial growth in urine culture, we do not recommend any treatment in patients with neurogenic LUTD presenting asymptomatic bacteriuria. References: (1) Stöhrer M, Blok B, Castro-Diaz D, ChartierKastler E, Del Popolo G, Kramer G, Pannek J, Radziszewski P, Wyndaele JJ. EAU guidelines on neurogenic lower urinary tract dysfunction. Eur Urol 2009; 56:81-8. disorders. This preliminary investigation determined the amount and intensity of physical activity undertaken during inpatient SCI rehabilitation. Methods: Participants in this observational study were consecutive admissions to two Canadian inpatient SCI rehabilitation centres. Participants were assessed with the Physical Activity Recall Assessment for People with Spinal Cord Injury (PARA-SCI).2 The PARA-SCI categorizes the intensity of activities as nothing, mild, moderate, or heavy and documents time spent on activities. The PARA-SCI was administered on two days near admission and again, near discharge for each patient and averaged to obtain activity for a typical weekday. A 2x4 mixed model ANOVA was conducted to explore the relationship between minutes of physical activity and physical activity intensity at admission and discharge from inpatient SCI rehabilitation. Results: The 22 subjects in this investigation were 48±15 years old. Average time from injury to rehabilitation admission was 24±13 days. Nineteen individuals were traumatic and 3 non-traumatic;16 had incomplete injuries, 6 were complete. There was no statistically significant interaction or time effect. The main effect for intensity yielded significance [F(3, 84)=71.7, p= 0.0005]. Post-hoc analysis indicated that the mean score for time spent in activities classified as nothing was significantly higher than all other intensities. Mild physical activity also significantly differed from heavy intensity. Time in moderate and heavy intensity did not differ significantly from each other. P2-25 Self-Reported Physical Activity of Individuals with SCI at Admission and Discharge from Inpatient Rehabilitation D. Zbogar1, J. Eng2, A. Krassioukov3, W.C. Miller4, M. Verrier5 1 , Rehabilitation Research Lab, GF Strong Rehab Centre, Vancouver/BC/CANADA, 2, Department of Physical Therapy, Faculty of Medicine, University of British Columbia, Vancouver/BC/CANADA, 3, University of British Columbia Physical Medicine and Rehabilitation, Vancouver/BC/CANADA, 4 , Department of Occupational Sciences & Occupational Therapy, Faculty of Medicine, University of British Columbia, Vancouver/BC/CANADA, 5, Toronto Rehabilitation InstituteUniversity Health Network, Toronto/ON/CANADA Background: Little is known about the amount of physical activity experienced by individuals with spinal cord injury (SCI) during inpatient rehabilitation. Physical activity early after a SCI is thought to be important for its benefits in optimizing recovery1 as well as its ability to reduce secondary complications like cardiovascular disease and autonomic 68 That there was no significant change in activity levels from admission to discharge is notable. We anticipated increasing levels of physical activity with time in inpatient rehabilitation as functional recovery occurred. Of relevance, it appears the minimum threshold for physical activity for individuals with chronic SCI3 is exceeded in this group, as moderate (M=94.68) and heavy activity (M=35.69) account for above 20 minutes of time. What remains to be elucidated is whether these activities are truly aerobic in nature. Review of heart rate data collected during the day will be analyzed to answer this question. References: 1. Sumida, M., et al. (2001) Arch Phys Med Rehabil, 82, 391-5. 2. Ginis, K. A., et al. (2005) Med Sci Sports Exerc, 37, 1099111. 3. 2011 Canadian Physical Activity Guidelines, www. sciactioncanada.ca/guidelines P3-01 The Acute Effects of Circulating Cytokines on Peripheral Nerve Function in Humans D. Allison, L. Green, D. Gabriel, B. Roy, G. Inglis, D. Ditor Brock University, St Catharines/ON/CANADA Background: A chronic elevation in circulating cytokine concentrations is typically observed following spinal cord injury (SCI) (Davies et al., 2007). This elevation has been shown to be particularly pronounced during the presence of a secondary health complication but is also evident even when no complications are apparent (Hayes et al., 2002). Although cytokines play a pivotal role in the inflammatory response, potential detrimental effects concerning nerve function have also been shown. When examined in ex vivo animal models, an acute elevation in the cytokine tumour necrosis factor-α was shown to cause reductions in the compound action potential and a depolarization of the resting membrane potential of the excised spinal cord (Davies et al., 2006). If cytokines have similar detrimental effects on the central or peripheral nerves of humans, individuals with chronically elevated levels, such as those with SCI, would be at the highest risk. The potential for such molecularly-based disruptions may limit the motor and sensory capabilities of individuals following SCI by impacting structurally healthy neural tracts. Methods: The notion of a peripheral neuropathy contributing to motor and sensory impairment is often neglected following SCI due to the more evident issues associated with central damage. The current study investigated the acute effects of circulating cytokines on peripheral nerve function in humans. Nerve conduction velocity (NCV) and several measures of physical function (grip strength, grip endurance and finger dexterity) were examined in 12 college-aged, able-bodied males prior to and following the induction of a cytokine spike via one hour of vigorous cycling exercise (65% heart rate reserve). The use of able-bodied subjects allowed for outcome measures to be examined under basal cytokine levels as well as exercise-induced elevated levels. Outcome measures were examined at 1 hour, 2 hours and 24 hours following the cytokine-inducing exercise bout due to the potential delay for channelopathic effects. Results: A significant positive correlation was found between the cytokine interleukin-6 (IL-6) and NCV at 2 hours postexercise (r=0.606, p=0.048). A significant negative correlation was found between the cytokine interleukin-1 receptor antagonist (IL-1ra) and NCV at 24 hours post-exercise (r=0.652, p=0.021). A significant positive correlation was also found between IL-1ra and endurance at 1 hour post-exercise (r=0.643, p=0.033). As such, it would seem that certain cytokines such as IL-6 may potentially act to enhance nerve function while other cytokines such as IL-1ra may have negative effects on the nerve and reduce NCV. If certain cytokines are to have detrimental effects on nerve function, future research may be directed towards methods of reducing chronic elevations or preventing their effects. In addition, the current evidence also indicates a potentially beneficial neural effect from certain cytokines, and this necessitates the examination of a wider variety of cytokines and other molecules for such benefits. This may allow for some degree of peripheral neurological improvement in individuals with chronic SCI and the enhancement of motor, sensory and autonomic function in this population. References: Davies et al. (2006) Davies et al. (2007) Hayes et al. (2002) P3-02 Mapping the Interactions of Chronic and Acute Noxious Sensations in the Spinal Cord M. Beynon, R.L. Bosma, C.E. Dobek, P.W. Stroman Center for Neuroscience, Queen’s University, Kingston/ CANADA Background: Attention and emotion play important roles in modifying the perception of pain. By influencing attention and emotion, interactions between two painful stimuli may alter the perception of one or both stimuli, such as heightening pain anxiety, or dividing attention between the two stimuli. Such interactions are important, both for our understanding of pain processing, and for developing means of studying effects of chronic pain with fMRI. Therefore, the primary aim of this study is to determine the neural responses in the spinal cord to multiple, competing noxious thermal stimuli. Methods: Healthy participants underwent functional MRI of the spinal cord using our established methods for data acquisition and analysis. Each participant was exposed to five noxious thermal stimulation conditions involving a hot intermittent stimulus (acute) on the right hand. Simultaneously, a constant stimulus (chronic) at two different temperatures (hot and cold) was applied on either the right or left hand (C6 dermatome). Thermal stimulation was just below (-0.3°C for hot) or above (+0.3°C for cold) participants’ measured pain thresholds. The order and combination of stimuli was counter-balanced across participants. Results: show that the addition of a chronic thermal stimulus to the C6 dermatome modulates the acute pain response in the spinal cord at the C6 segment. The patterns of activity appear to vary with the simultaneous application of a constant 69 chronic stimulus, and whether the two stimuli (chronic and acute) are applied to the same, or opposite, hands. However, the magnitude of the responses do not show any dependence, and are relatively constant across all combinations of tested thermal stimuli. The results to date therefore suggest that interactions between constant noxious stimuli, such as chronic pain, and intermittent stimulation (typically used for fMRI), may reveal important information about spinal cord function and the characteristics of such interactions. References: 1. Cahill, C.M. & Stroman, P.W. (2011). Mapping of neural activity produced by thermal pain in the healthy human spinal cord and brainstem: a Functional MRI Study. Magnetic Resonance Imaging, 29, 342-352. 2. Figley, C.R., Leitch, J.K. & Stroman, P.W. (2010). In contrast to BOLD: Signal enhancement by extravascular water protons (SEEP) as an alternative mechanism of endogenous fMRI signal change. Magnetic Resonance Imaging, 28, 1234-1243. 3. Figley, C.R. & Stroman, P.W. (2009). Development and validation of retrospective spinal cord motion time-course estimates (RESPITE) for spin echo spinal fMRI: Improved sensitivity and specificity by means of a motion-compensating general linear model analysis, 44,421-427. each participant. Data were analyzed by means of a general linear model analysis. Results: This study demonstrates that classical music modulates spinal cord activity in response to thermal stimulation just below heat pain threshold. The activity was investigated at C8 as well as adjacent segments. Results show distinct time course activity in both C6 and C8 that increases or decreases in response to the change in music. No distinct pattern of effect across participants was observed with comparing preferred music to other types (Aversive, Neutral, No music), or comparing activity with subjective ratings. This study gives insight to spinal mechanisms and structures that are involved in pain analgesia and music therapy, which may enhance the efficiency of the techniques for its widespread clinical use. References: Evans, D. (2002). The effectiveness of music as an intervention for hospital patients: a systematic review. Journal of Advanced Nursing, 37, 8-18. Stroman, P. W., Coe, B. C., & Munoz, D. P. (2011). Influence of attention focus on neural activity in the human spinal cord during thermal sensory stimulation. Magnetic Resonance Imaging, 29, 9-18. P3-03 P3-04 Influence of Classical Music on Neural Activity and Pain Response in the Spinal Cord Using Functional Magnetic Resonance Imaging An In Vivo Experimental Platform for Chronic Spinal Cord Injury C.E. Dobek, R.L. Bosma, M.E. Beynon, P.W. Stroman Center for Neuroscience Studies, Queen’s University, Kingston/ CANADA X. Li1, J. Cui1, C. Wen1, K.D. Luk2, Y. Hu3 1 , Rm 108, Blk C, The Duchess of Kent Children’s Hospital, Hong Kong/HONG KONG, 2, The Department of Orthopedics & Traumatology, The University of Hong Kong, Hong Kong/HONG KONG, 3, Flat A, 5/F, Blk D, The Duchess of Kent Children’s Hospital, Hong Kong/HONG KONG Background: Music therapy for pain reduction has dated back thousands of years and is still widely used today, but little is known about the underlying neural mechanisms involved. With functional MRI of the spinal cord (spinal fMRI), we can objectively view the functional changes involved in music therapy in the spinal cord. This study aims to help identify the mechanisms of descending pain modulation and further clarify the analgesic effects of music. Background: Spinal cord injury in a chronic process is commonly happened in degenerative spinal disorders[1]. The putative mechanism is that the compression of the enclosed cord leading to tissue injury , ischemia and neurological impairment. Yet the exact pathophysiology was still unclear. An appropriate animal model, which reproduced chronic compression of the cord, is helpful for better understanding the disease. Methods: Spinal fMRI studies were carried out using healthy, English speaking, right-handed, non-musician controls. Thermal stimulation was applied in a block paradigm of 4 stimulations per trial, with the stimulation site corresponding to the C8 dermatome (right hand). The stimulation temperature was set 0.3oC lower than heat pain threshold determined prior to imaging. In addition to thermal stimulation, participants listened to familiar classical music (Preferred) paired with either scrambled classical music (Aversive), reverse classical music (Neutral), or no music for each trial. After each trial, participants reported subjective ratings for their temperature discomfort on a scale from 0-10. There were 4 trials in total for Methods: 1.Using adult Sprague-Dawley rats as in vivo animal model, we inserted a water-absorbing urethane-containing polymer, which would expand upon absorbing tissue fluid, into the spinal canal at posterior-lateral side of the C5-C6 region to induce chronic compression to the cervical spinal cord. At 1w, 4w and 12w post-operatively, we evaluated functional integrity of the spinal cord by neuro-electrophysiology method and observed the spinal cord impairment under MRI, Micor-CT and histological studies. 2.In order to validate the chronic compression feature of this novel animal model, we repeated the surgical intervention to 70 the rat model mentioned above. BBB score and MRI had been employed to evaluate the functional and structure integrity of the compressed spinal cord at 4, 12, 48, 72 hours and 1 week post-operatively. Results: 1.At 1w, 4w and 12w post-operatively, the impairment of functional integrity of the spinal cord was confirmed by neuro-electrophysiology changes respectively which showed prolonged latency and /or decreased amplitude. Under axial T2W and diffusion tensor images (DTI) by 7-tesla MRI, it was revealed that the diffusivity of the white matter of the cord dropped at the compression site which was echoed by less myelin stained by luxol fast blue. The increase of intensity of contrast medium was also found in the gray matter at the compression site under in vivo micro-CT, as well as the presence of the cavities and increased blood vessels correspondingly. The representative pathological changes of the injured spinal cord were validated with histological studies. 2.The results were well validated with the histological evaluation (HE and myelin stain). Although spinal cord compression and ultrastructure damage were found in MRI T2 image and histological observation separately, BBB score didn’t show acute motor dysfunction in different time points. None of acute spinal cord injury changes, such as significant decrease of motoneurons in ventral horn, blood vessel rupture/hemorrhage[2], edema, macrophage infiltration and inflammatory demyelination[3], presented in histological consequences. It demonstrated that this animal model was consistent with the early-stage pathological changes of chronic spinal cord injury, differing acute injury. This reliable and stable research platform may contribute to the revelation of underlying pathological mechanism, biological investigation and relative drug management development. References: [1] Fehlings MG, Skaf G. A review of the pathophysiology of cervical spondylotic myelopathy with insights for potential novel mechanisms drawn from traumatic spinal cord injury. Spine 1998;23:2730–7. [2] Kakulas BA. Neuropathology: the foundation for new treatments in Cord 42:549–563, 2004. spinal cord injury. Spinal [3] Totoiu MO, Keirstead HS. Spinal cord injury is accompanied by chronic progressive demyelination. J Comp Neurol 486:373–383, 2005 P3-05 Dietary Treatments for Spinal Cord Injury (CNOSP), Department of Orthopaedics, University of British Columbia, Vancouver/BC/CANADA Background: Each year, over 1,500 Canadians sustain a new Spinal Cord Injury, and join over 40,000 Canadians living with traumatic SCI. Other than stabilizing the broken spinal column surgically and providing rehabilitation training there are no effective treatments for the spinal cord damage. Many experimental therapies for spinal cord injury in animals aim to prevent any further damage to the cord after the initial injury. We are studying the effects of simple dietary strategies, to improve functional recovery in animal models of spinal cord injury. Previously, we have discovered that fasting every other day is beneficial after SCI. However, given that a fasting regimen may be met with little enthusiasm from patients, dietitians and physicians, we felt the need to further explore the implementation of alternative dietary strategies. Hence, in this study we investigated a high-fat, and very low-carbohydrate regimen known as ketogenic diet (KD) as a possible neuroprotective treatment for acute cervical SCI using a rodent model. Methods: Four hours following C5 hemi-contusion injury, adult male rats were allowed access to either a standard carbohydrate-based diet, or KD. Forelimb function was evaluated for 14 weeks. Results: Following SCI, KD-treated rats showed improved usage and motor control of the affected paw during rearing and grooming behavior. In addition, KD regimen improved pellet-retrieval of the ipsilateral limb and recovery of wrist and digit movements. Importantly, after returning to a standard carbohydrate-based diet after 12 weeks of KD treatment, the beneficial effects on forelimb function remained stable for at least 6 weeks. No effects on body weight gain, cholesterol levels or bone morphology/density were observed. References: A short term KD regimen enhances functional recovery from SCI in rats and has lasting therapeutic effects without apparent side effects. From a translational perspective, our results mandate the reconsideration of standard clinical practices, which have traditionally promoted high carbohydrate nutritional content in acute SCI patients. The optimization of such aspects of patient care is highly desirable, particularly when the influence of nutritional status on secondary injury becomes apparent in animal studies. We encourage opening further dialogue on this important aspect of patient care in acute SCI, given the limited interventions currently available for this devastating injury. F. Streijger1, W. Plunet1, J.H.T. Lee1, J. Liu1, C.K. Lam1, S.E. Park1, B. Hilton1, B.L. Fransen1, K.A.J. Matheson1, P. Assinck1, B.K. Kwon2, W. Tetzlaff1 1 , ICORD (International Collaboration On Repair Discoveries) Blusson Spinal Cord Centre, Vancouver/BC/CANADA, 2, Combined Neurosurgical and Orthopaedic Spine Program 71 P3-06 Establishing a Model Spinal Cord Injury in the African Green Monkey for the Preclinical Evaluation of Biodegradable Polymer Scaffolds Seeded With Human Neural Stem Cells E. Wirth1, C. Pritchard2, J. Slotkin3, D. Yu4, H. Dai5, M. Lawrence6, R. Bronson7, F. Reynolds1, Y. Teng4, E. Woodard8, R. Langer2 1 , InVivo Therapeutics Corporation, Cambridge/MA/UNITED STATES OF AMERICA, 2, Department of Chemical Engineering, Massachusetts Institute of Technology, Cambridge, MA/ UNITED STATES OF AMERICA, 3, Washington Brain & Spine Institute, Washington, DC/UNITED STATES OF AMERICA, 4 , Department of Neurosurgery, Brigham and Women’s Hospital, Boston, MA/UNITED STATES OF AMERICA, 5, Department of Neuroscience, Georgetown University Medical Center, Washington, DC/UNITED STATES OF AMERICA, 6, RxGen, Inc., Hamden, CT/UNITED STATES OF AMERICA, 7, Department of Pathology, Harvard Medical School, Boston, MA/UNITED STATES OF AMERICA, 8, Department of Neurosurgery, New England Baptist Hospital, Boston, MA/ UNITED STATES OF AMERICA Background: Given the involvement of post-mitotic neurons, long axonal tracts and incompletely elucidated injury and repair pathways, spinal cord injury (SCI) presents a particular challenge for the creation of preclinical models to robustly evaluate longitudinal changes in neuromotor function in the setting in the presence and absence of intervention. While rodent models exhibit high degrees of spontaneous recovery from SCI injury, animal care concerns preclude complete cord transections in non-human primates and other larger vertebrate models. Methods: To overcome such limitations a segmental thoracic (T9–T10) spinal cord hemisection was created and characterized in the African green monkey. Physiological tolerance of the model permitted behavioral analyses for a prolonged period post-injury, extending to predefined study termination points at which histological and immunohistochemical analyses were performed. Four monkeys were evaluated (one receiving no implant at the lesion site, one receiving a poly(lactide-co-glycolide) (PLGA) scaffold, and two receiving PLGA scaffolds seeded with human neural stem cells (hNSC)). All subjects exhibited BrownSéquard syndrome 2 days post-injury consisting of ipsilateral hindlimb paralysis and contralateral hindlimb hypesthesia with preservation of bowel and bladder function. Results: A 20-point observational behavioral scoring system allowed quantitative characterization of the levels of functional recovery. Histological endpoints including silver degenerative staining and Iba1 immunohistochemistry, for microglial and 72 macrophage activation, were determined to reliably define lesion extent and correlate with neurobehavioral data, and justify invasive telemetered electromyographic and kinematic studies to more definitively address efficacy and mechanism. References: Teng YD, Lavik EB, Qu X, Park KI, Ourednik J, Zurakowski D, Langer R, Snyder EY. Functional recovery following traumatic spinal cord injury mediated by a unique polymer scaffold seeded with neural stem cells. Proceedings of the National Academy of Sciences of the United States of America 2002;99(5):3024–9. Courtine G, Bartlett Bunge M, Fawcett JW, et al. Can experiments in nonhuman primates expedite the translation of treatments for spinal cord injury in humans? Nature Medicine 2007;13(5):561–6. Disclosure: Pritchard, Slotkin, Dai, Lawrence, Reynolds, Woodard, and Langer are all current or former employees, advisers, or contracted researchers of InVivo Therapeutics Corporation, the sponsor of the study in the abstract (R&D stage). P3-07 A Model for Bridging the Translational Valley of Death in Spinal Cord Injury N. Thorogood, B. Barrable, V. Noonan, P. Joshi, M. Dvorak Rick Hansen Institute, Vancouver/CANADA Background: To improve health care outcomes with costeffective treatments and prevention initiatives, basic health research must be translated into clinical application and implementation, a process commonly referred to as translational research. Despite the amount of funding that supports basic research, few basic research discoveries achieve their fullest potential. It is estimated that only 14% of health-related scientific discoveries enter into medical practice and that it takes an average of 17 years for research evidence to extend into clinical practice. 1 The transition from benchto-bedside research is so fraught with obstacles that it is often referred to as the “valley of death”. Methods: The Rick Hansen Institute (RHI) has developed a unique Praxis Model for translational research in the field of spinal cord injury (SCI). Praxis can be defined as the process by which a theory, lesson, or skill is enacted, practiced, embodied or realized. At RHI this means bringing knowledge into action and represents the process by which translational research is practiced to bridge the “valley of death” in the research and commercialization continuum of SCI discoveries; to improve healthcare outcomes for people with SCI and decrease the financial impact on the healthcare system. Translational research inherently requires multi- disciplinary teams, multi-sector partnerships and diverse funding; therefore, distinct from traditional research institutes, the Praxis Model combines the attributes of a granting/sponsor agency, early commercialization investor/incubator, as well as a research network and centre. RHI’s Praxis Model uses four pillars of implementation to move outputs into outcomes – for knowledge to be translated into action – at the institutional, professional, multi-disciplinary and commercialization level. Results: At the hub of a research network, RHI uses the Praxis Model to unite a diverse group of shareholders and provide support for a national SCI registry, clinical trials, validation studies, implementation, best practice dissemination and early commercialization. The Network provides an opportunity for partnerships to share data and innovative ideas for SCI solutions. RHI has participated and supported over 60 studies since 2007 and has engaged researchers from nine countries, 46 academic institutions and various accreditation and professional associations. A national network was developed into an international network and connected with additional existing networks. Currently, the model is being independently evaluated to determine its strengths and limitations. Examples of RHI initiatives using the Praxis Model and results of the evaluation will be presented. The RHI has developed an innovative solution to move knowledge into action. The Praxis Model strives to lead collaboration across the global SCI community by providing resources, infrastructure and knowledge. Lessons learned in developing the Praxis Model may assist other organizations dealing with similar translational research challenges. References: 1. Balas EA, Boren SA. Yearbook of Medical Informatics: Managing Clinical Knowledge for Health Care Improvement. Stuttgart, Germany: Schattauer, 2000. P3-08 Development of a Knowledge Translation Program Among Spinal Cord Injury Patients in Acute Care M. Berube1, M. Albert1, J. Chauny1, D. Contandriopoulos2, A. Dusablon1, M. Prud’Homme Lemaire1, A. Gagne1, S. Parent1, E. Laflamme1, N. Boutin1, S. Delisle1, S. Lacroix3, F. Bedard3, J. Macthiong1 1 , Hôpital du Sacré-Coeur, Montreal/CANADA, 2, University of Montreal, Montreal/QC/CANADA, 3, Hôtel Dieu de St-Jérôme, St-Jérôme/CANADA Background: Background: Clinical guidelines are a common tool to synthesize new knowledge and inform health care professionals, but it turns out that these guides are sometimes unknown or not used comprehensively. The difficulty to change clinical practice independently of the quality of the research findings synthesis is well documented. To overcome this problem, an analysis of the barriers for translation of knowledge to practice must be made. In the Western Quebec Expertise Center, this analysis revealed that the implementation of recommendations from clinical guidelines was complicated by factors associated with the context, as well as available human and financial resources. Several knowledge translation strategies were therefore identified to reduce the scope of those barriers, including the development of interactive educative online activities for all health care professionals involved with spinal cord injury patients, care map and educational activities provided by resource persons in practice. Purpose: This project granted by the Quebec Health Care Research Funds aims to systematically implement recommendations included in the Consortium for Spinal Cord Injury Medicine guidelines (2008) in the Western Quebec acute care continuum. To meet this objective, the development of a knowledge translation program was recently undertaken. Methods: Method: This project, based on the knowledge to action cycle model (Graham et al., 2006), will be conducted in three main phases, namely: the selection and adaptation of knowledge to organizational contexts, the development of knowledge transfer strategies, and the validation of those strategies. Results: Results: To date, the first phase of the project has been completed. Indeed, an expert committee composed of orthopaedists, emergency physicians, an intensivist, nurses, physiotherapists, occupational therapists and a respiratory therapist from different hospitals has been created for the selection and adaptation of knowledge to organizational contexts. The members of this committee have selected recommendations based on level of evidence, clinical relevance and feasibility of implementation. Thereafter, they reviewed the literature from 2008 to 2011 considering that the guidelines were published in 2008. Selected recommendations were reconsidered in light of new research findings after which, indicators to evaluate clinical practice were identified. Finally, targeted recommendations and practice indicators were presented to clinicians of the involved services as well as to hospital administrators. A new category of recommendations was added and few changes were brought to clinical indicators after this consultation process. Conclusions: Upon completion of this project, the gap between knowledge production and application in practice will be reduced, and a structure to enhance the quality of care will be implemented. Consequently, we estimate that outcomes obtained among the concerned population of patients will be improved. Advancements in knowledge translation research in addition to improvements in the training of health care professionals (current and future) involved with spinal cord injury patients are also expected. References: Consortium for Spinal Cord Medicine (2008). Early Acute Management in Adults with Spinal Cord Injury: A Clinical Practice Guidelines for Health-Care Professionals. Paralyzed Veterans of America: Washington, DC. Graham et al. (2006). Lost in knowledge translation: time for a map? Journal of Continuous Education in the Health Professions, 26, 13-24. 73 P3-09 P3-10 Critical Appraisal Tools for Preclinical Studies in Spinal Cord Injury Research Investigating Knowledge Translation Between Biomedical Researchers, Knowledge Facilitators and Wheelchair Users J. Cragg, F. Warner, W. Plunet, M. Ramer, J. Borisoff International Collaboration on Repair Discoveries, Vancouver/ CANADA Background: Critical appraisal is an essential skill required by clinicians and scientists alike. Critical appraisal tools exist for several reasons. For example, critical appraisal tools facilitate both formal (eg. peer review and systematic review) and informal (eg. journal club) review processes. By providing a checklist of agreed-upon components of high quality trials/ experiments, such as randomization, blinding, and use of appropriate statistical methods, they provide a user-friendly, standardized approach to the review process. Further, they have the added benefit of being able to‘reverse engineer’ the criteria for study design. That is, experimenters can implement the components into both the design and reporting of their studies. There does not yet exist readily available, standardized, and piloted critical appraisal tools with a specific pre-clinical discovery science focus in the area of spinal cord injury (SCI) research. Methods: Because several critical appraisal tools already exist in benchside stroke research and in clinical practice, we have modified these tools to fit within a SCI bench science context, and have also piloted these tools [1]. Results: Here, we describe the development, piloting, and suggested implementation strategies of a new checklist specifically for animal experimentation. We also take this opportunity to highlight several areas where we feel SCI preclinical discovery science must improve with reference to some of the areas on the checklist. Improving the quality and consistency of conducting and reporting trials is necessary (but perhaps not sufficient) to move forward in SCI research. References: Richard F. Heller, Arpana Verma, Islay Gemmell, Roger Harrison, Judy Hart, Richard Edwards, Critical appraisal for public health: A new checklist, Public Health, Volume 122, Issue 1, January 2008, Pages 92-98. C. Goudie, B. Hallgrimsson Carleton University, Ottawa/ON/CANADA Background: Optimal wheelchair seating can play a crucial role in the physical health of wheelchair users, especially those with spinal cord injury related conditions. For this reason, wheelchair users must make informed decisions when choosing appropriate wheelchair seating systems and are encouraged to base their choices on accessible and reliable information at the time of assessment. Such information can be provided by therapists and wheelchair seating specialists, which include manufacturers and designers - also considered to be knowledge facilitators. Recommendations by knowledge facilitators are often made using evidence-based knowledge and practices, however a need has been identified for future recommendations to be based on more recent, relevant and reliable biomedical research. This need is associated with the abundance of biomedical research conducted annually and resulting data in the form of journal articles and publications. The issue facing knowledge facilitators is that the research findings are often far too complex to disseminate for immediate or practical use. This creates a gap in the knowledge translation process for many important stakeholders, which can potentially impact the final decision-making process of the wheelchair user. The following paper investigates knowledge translation and the divide between researchers and facilitators. The perceived benefits of converting knowledge translation processes into that of knowledge exchange will also be explored. The results will review the current knowledge-to-action cycle in the translation process as used by both researchers and designers of wheelchair seating. A focus will be placed on identifying potential areas for improvement in delivering timely, disseminated research findings, individually targeting each category of wheelchair seating stakeholder. Methods: Methodology involves the creation of a workshop for associated wheelchair seating stakeholders. Participants will be engaged in dialogue about existing methods of knowledge translation, and brainstorming will be conducted to understand how to improve processes between specific vested stakeholders in wheelchair seating. Results: The desired outcome will potentially result in a revised framework and recommendations of improved knowledge translation processes between biomedical researchers, knowledge facilitators and wheelchair users. References: Altenstetter, C. (2008). Medical Devices. Transaction Publishers. New Brunswick, USA and London, UK. pp.1-13. 74 Armstrong, R., Waters, E., Dobbins, M., Lavis, J.N., Petticrew, M., Christensen, R. (2011). Knowledge Translation Strategies for Facilitating Evidence-Informed Public Health Decision Making Among Managers and Policy Makers (Protocol). The Cochrane Collaborative. The Cochrane Library, Issue 6. John Wiley & Sons, Ltd. Bennett, G., & Jessani, N. (2011). The Knowledge Translation Toolkit Bridging the Know-Do Gap, a Resource for Researchers. Ottawa: International Development Research Centre. Bero, L. A., Grilli, R., Grimshaw, J. M., Harvey, E., Oxman, A. D., & Thomson, M. A. (1998). Getting Research Findings into Practice: Closing the Gap Between Research and Practice: An Overview of Systematic Reviews of Interventions to Promote the Implementation of Research Findings. BMJ: British Medical Journal, 317(7156), 465-468. Caplan, N. (1979). The Two Communities Theory and Knowledge Utilization. American Behavioral Scientist. Vol 22. No. 3, January-February, 1979. University of Michigan: Sage Publications. Dijkers, M., Brown, M., Gordon, W. (2008). Getting Published and Having an Impact: Turning Rehabilitation Research Results Into Gold. Mount Sinai School of Medicine, Department of Rehabilitation Medicine, New York, NY. Focus: A Publication of the National Center for the Dissemination of Disability Research (NCDDR), Technical Brief 19, 1-16. Dykes, T. H., Rodgers, P. A., & Smyth, M. (2009). Towards a New Disciplinary Framework for Contemporary Creative Design Practice. CoDesign, 5(2), 99-116. Fiore, S. (2008). Interdisciplinarity as Teamwork. Small Group Research, 39(3), 251-277. Fries, R. C. (2001). Handbook of Medical Device Design. New York: M. Dekker. Fries, R. C. (2006). Reliable Design of Medical Devices (2nd ed. ed.). Boca Raton, Fla: CRC/Taylor & Francis. Freemantle, N., Grilli, R., Grimshaw, J., Oxman, A. (1994). Implementing Findings of Medical Research: The Cochrane Collaboration on Effective Professional Practice. Quality in Health Care, 1995; 4:45-47. British Medical Journal. Gagnon, M. L. (2011). Moving Knowledge to Action Through Dissemination and Exchange. Journal of Clinical Epidemiology, 64(1), 25-31. Gibbons, M. (2008). In Michael Gibbons. (Ed.), Why is Knowledge Translation Important? Grounding the Conversation. Edmonton, AB: Knowledge Utilization Studies in Practice, University of Alberta, 2008. Gilman, B. L., Brewer, J. E., & Kroll, M. W. (2009). Medical Device Design Process. 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, , 5609-5612. Graham, I. D., Logan, J., Harrison, M. B., Straus, S. E., Tetroe, J., Caswell, W., et al. (2006). Lost in Knowledge Translation: Time for a Map? Journal of Continuing Education in the Health Professions, 26(1), 13-24. Haines, A., & Donald, A. (1998). Getting Research Findings into Practice: Making Better Use of Research Findings. BMJ: British Medical Journal, 317(7150), 72-75. Haynes, B. (1998). Getting Research Findings into Practice: Barriers and Bridges to Evidence Based Clinical Practice. BMJ: British Medical Journal, 317(7153), 273. Hollister, S. J. (2009). Scaffold Engineering: A Bridge to Where? IOP Science: Biofabrication. IOP Publishing 2011. Published March 20, 2009. Holmes, K. S. (2011). Medical Devices 101. University of Ottawa Heart Institute. In Class Lecture, November 15, 2011, Carleton University. Jones, J. C. (1992). Design Methods (2nd ed. ed.). New York: Van Nostrand Reinhold. Kucklick, T. R. (2006). The Medical Device R & D Handbook. Boca Raton: Taylor & Francis. Lee, E. S., McDonald, D. W., Anderson, N., & TarczyHornoch, P. (2009). Incorporating Collaboratory Concepts into Informatics in Support of Translational Interdisciplinary Biomedical Research. International Journal of Medical Informatics, 78(1), 10-21. Liyanage, C., Elhag, T., Ballal, T., & Li, Q. (2009). Knowledge Communication and Translation – A Knowledge Transfer Model. Journal of Knowledge Management, 13(3), 118-131. Malhotra, S., Laxmisan, A., Keselman A., Chiellini, E., Zhang, J., Patel, V. L. (2004). The Design Phase of Critical Care Devices: A Cognitive Approach. Elsevier: Science Direct, Journal of Biomedical Informatics 38 (2005), p.34-50. Mills, N. (2007). Polymer Foams Handbook: Engineering and Biomechanics Applications and Design Guide. Elsevier: ButterworthHeinemann. Oxford, UK & Burlington, USA. Norman, D. (2012). The Research-Practice Gap. ACM CHI Magazine, Interactions Volume 17, Issue 4. 75 Norman, D. (2012). Technology First, Needs Last. ACM CHI Magazine, Interactions Volume 17, Issue 2. Privitera, M. B. & Murray, D. L. (2009). Applied ergonomics: Determining User Needs in Medical Device Design. 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, , 5606-5608. Privitera, M. B., & Johnson, J. (2009). Interconnections of Basic Science Research and Product Development in Medical Device Design. 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, , 55955598. Pugh, S. (1991). Total Design: Integrated Methods for Successful Product Engineering. Wokingham, England; Reading, Mass: Addison-Wesley Pub. Co. Quinlan, E., & Robertson, S. (2010). Mutual Understanding in Multi-Disciplinary Primary Health Care Teams. Journal of Interprofessional Care, 24(5), 565-578. Rogers, J., & Martin, F. (2009). Knowledge Translation in Disability and Rehabilitation Research: Lessons From the Application of Knowledge Value Mapping to the Case of Accessible Currency. Journal of Disability Policy Studies, 20(2), 110-126. Stokes, D. E. (1997). Pasteur’s Quadrant: Basic Science and Technological Innovation. Washington, DC. Brookings Institution Press. Straus, S. (2009). Managing Evidence Based Knowledge: The Need for Reliable, Relevant and Readable Sources. Analysis, Canadian Medical Association Journal (CMAJ), 180(9). Sudsawad, P. (2007). Knowledge Translation: Introduction to Models, Strategies, and Measures. The University of Wisconsin-Madison: The National Center for the Dissemination of Disability Research. Thompson, M. A. (1998). Closing the Gap Between Nursing Research and Practice. BMJ: British Medical Journal, 1(1), 7-8. Wiklund, M. E., & Wilcox, S. B. (2005). Designing Usability into Medical Products. Boca Raton: CRC Press. P3-11 Practical Steps Towards Knowledge Mobilization in Spinal Cord Injury C. Koning1, L. Mumme1, M. Mark1, C. Huitsing1, K. Bayless1, N. Hodgkinson1, J. Hsieh2, M. Duda2, J. Brown3 1 , Glenrose Rehabilitation Hospital, Edmonton/CANADA, 2, National Implementation Research Network, Ontario/ON/ CANADA, 3, National Implementation Research, Carrboro/ UNITED STATES OF AMERICA Background: Effective best practices adoption requires an implementation framework that systematically addresses barriers and facilitators in a real-life clinical context and that engages all members of the community of practice (CoP) for sustained and continuous quality improvement (CQI). Currently, a CoP comprised of six Canadian rehabilitation sites across three provinces (AB, ON, PQ) are engaged in a Spinal Cord Injury Knowledge Mobilization Network (SCI KMN) using an evidence-informed implementation framework (Fixen et al., 2005; NIRN: National Implementation Research Network). The framework provides implementation science tools to move through the four phases of implementation (exploration, installation, initial implementation, and final implementation) in order to successfully integrate best practices in pressure ulcer prevention and management for patients with a SCI. With support from the NIRN, two pressure ulcer prevention and management “best practice” areas were identified by CoP consensus: 1) risk assessment and 2) patient education. This presentation focuses on the implementation steps taken to date on these two areas in the inpatient SCI Program to date at the Glenrose Rehabilitation Hospital. Methods: Best practices (BP) and associated performance measures were identified through a Delphi consensus exercise involving all members of the CoP towards operationalizing the two BPs chosen for implementation (risk assessment and patient education). Input was provided by a site implementation team (SIT) assembled under guidance from NIRN. Critical participants of the SIT included site leaders and clinical experts, as well as mentors able to build readiness for implementation at the clinical level. NIRN consultation at the Glenrose provided feedback on the readiness for implementation and solidified the local CoP at the Glenrose. SIT participants attended a two day implementation science (IS) educational “bootcamp” designed to increase awareness and understanding of the implementation framework and processes. The SIT meet weekly to apply IS tools to the installation phase of pressure ulcer risk assessment and patient education and provide input to CoP subcommittees for operationalization, data management, and knowledge communication. Results: 1) A workplan was developed to document the process. 2) A SIT was assembled that includes participants 76 who are able to influence site and program decision-making, have knowledge mobilization and clinical expertise. 3) Terms of reference outlining the function, key responsibilities and role of team members was developed. 4) Practice profiles outlining critical components and acceptable variations for implementation were developed. 5) Representatives participate in the CoP subcommittees including the Project Leadership Team, Transformation Specialist Team, Evaluation and Data Management Team and the Knowledge Management and Collaboration Team 6) A site specific communication plan was developed which is intended to build knowledge mobilization CoP at the Glenrose and Alberta Health Services. 7) Systems for documentation of the process were developed that enable replication of the implementation process to other BP initiatives. References: 1. Fixsen, D. L., Naoom, S. F., Blase, K. A., Friedman, R. M. & Wallace, F. (2005). Implementation Research: A Synthesis of the Literature. Tampa, FL: University of South Florida, Louis de la Parte Florida Mental Health Institute, The National Implementation Research Network (FMHI Publication #231). P3-12 Evaluation of Diffusion Tensor Magnetic Resonance Imaging to Improve Fiber Tract Assessment in Humans E. Tsai1, K. Rajamanickam2, B. Mendis3, T. Nguyen4, S. Chakraborty4 1 , University of Ottawa, Ottawa/ON/CANADA, 2, Ottawa Hospital Research Institute, Ottawa/ON/CANADA, 3, Ottawa Hospital Research Institute, Ottawa/CANADA, 4, The Ottawa Hospital, Ottawa/CANADA Background: Evaluation of successful therapeutic interventions in preclinical studies includes both functional assessments and axonal tracing studies. In humans, however, axon fiber tracing assessments are limited1. To improve fiber regeneration assessments in humans, we investigated the use of magnetic resonance diffusion tensor imaging (DTI) and fiber tractography to image spinal cord fiber tracts in humans and improve clinical correlation in patients with motor or sensory deficits. images and fractional anisotropy (FA) and MD values were measured in delineated regions of interest corresponding to the dorsal column (DC), corticospinal tract (CST) and spinothalamic tract (STT) bilaterally. Clinical status was obtained from the tractography clinical database. Patients with unilateral deficits were identified from the tractography database. Results: Twenty three subjects (healthy controls=8, patients with spinal lesions=15) were analyzed for this study. Two patients were excluded due to movement artifacts during scanning. Two additional patients were excluded as spinal instrumentation prevented analysis of images at the level of instrumentation. The remaining 11 patients (8 males:3 females) had a mean age of 51 years (17-77 years). There was no statistical difference between the left and right side of the DC, CST and STT for controls. In patients, FA mean values differed significantly (P < 0.05) between the affected tract compared to the contralateral tract. In 9/11 patients, differences in CST FA measurements correlated with clinical motor deficits. In the remaining 2, there were CST FA differences, but no noted motor deficits on physical examination. In patients with sensory deficits, 10/11 patients had differences in DC or ST FA measurements which correlated with clinical sensory deficits. In the remaining 1 patient, there were sensory tract FA measurement differences but no noted sensory deficit. MR DTI may improve imaging correlation with specific motor or sensory deficits and may also allow early identification of subclinical deficits. Improving the imaging correlation of patients with specific motor or sensory deficits can improve the selection of patients that will respond more appropriately to targeted and more specific therapeutic interventions (i.e. apply therapy for CST regeneration to patients with CST deficits as identified by MR DTI). It may also allow the evaluation of therapeutic strategies that may facilitate regeneration without any easily demonstrated clinical outcome (i.e. evaluation of regeneration of the thoracic spinal cord fibers that do not reach the level of the lumbar roots). Being able to evaluate axonal regeneration in humans will allow the critical evaluation and improvement of the therapeutic intervention. Further work on improving MR DTI correlation with clinical status is ongoing. References: 1. Tsai EC, et al. Journal of Histochemistry and Cytochemistry 49:1111-1122, 2001 Methods: Hospital ethics board approval was obtained and subjects underwent an axial spin-echo single-shot echoplanar generalized auto-calibrating partially parallel acquisition diffusion-weighted imaging sequence and routine MRI between August 2008 to November 2011. Mean diffusivity (MD) and first eigen vector fractional anisotropy maps were computed for all axial sections from mid C2 to C6 and tractography was used to visualize the course of the tracts. Matlab software was used to generate spinal cord tracking 77 P3-13 Early Surgical Decompression for Traumatic Cervical Spinal Cord Injury (SCI): A Cost-Utility Analysis and Feasibility Study M. Fehlings, J.C. Furlan Division of Genetics and Development, Toronto Western Research Institute, University Health Network, Toronto/ CANADA Background: Pre-clinical and clinical studies suggest that early surgery is potentially beneficial. This study compares early (≤24 hours since SCI) versus later surgical decompression of spinal cord in order to determine which approach is more cost effective in the management of patients with acute cervical SCI and to examine the potential barriers and ideal timelines for each step to early surgical decompression. Methods: A cost-utility analysis (CUA) was performed using data for the first year after cervical SCI. The perspective of a public health care insurer was adopted. Utilities are from the Surgical Trial in Acute Spinal Cord Injury Study. The reasons for delays in the management steps were classified into: (a) healthcare-related (“extrinsic”) and (b) patient-related (“intrinsic”) factors. Results: When considering the late decompression as the baseline strategy, the incremental cost-effectiveness ratio is US$8,523,852 per quality-adjusted life year (QALY) for patients with complete SCI and US$275,390/QALY for patients with incomplete SCI. The probabilistic analysis indicated that there is no clearly dominant strategy. Patients who underwent early surgery (n=21) and individuals who underwent later surgery (n=42) were comparable with respect to prehospital time (137 versus 185.5 min, respectively), time in a second general hospital prior to transfer to a spine center (369.5 versus 730.8 min) and time in the emergency department of a spine center (221.7 versus 226.4 min). However, patients who underwent early surgery had significantly shorter waiting time in the first care general hospital (577.6 versus 1982.1 min, respectively; p=0.0181), shorter waiting time for assessment by a spine surgeon (73.5 versus 274.4 min; p<0.0001) and shorter waiting time for a decision regarding surgical management (241.7 versus 832.3 min; p<0.0001). While both patient groups showed comparable time periods related to intrinsic factors, patients who underwent early surgery had a significantly shorter time period associated with extrinsic factors when compared with individuals who underwent later surgery (19.16 versus 71.28 hours, respectively; p<0.0001). Of note, the percentage of cases that were seen in one general hospital, two general hospital or three general hospital did not significantly differ between both groups (p=0.214). In conclusion, the results of our economic analysis suggests that, although no strategy is clearly superior to the other, early decompression of spinal cord can be more cost effective than 78 delayed surgery in approximately one quarter of the patients with complete SCI and one third of the individuals with incomplete SCI. Our benchmarking analysis suggests that health-related factors are key determinants of the timing from SCI to spinal cord decompression. Time in the general hospital and time of waiting for surgical decision were the most important causes of delays for surgical spinal cord decompression. Early surgery is feasible in the vast majority of the cases. References: Furlan JC, Noonan V, Cadotte DW, Fehlings M. Timing of decompressive surgery after traumatic spinal cord injury: An evidence-based examination of pre-clinical and clinical studies. JOURNAL OF NEUROTRAUMA 2010 March 4. [Epub ahead of print]. P3-14 Institute for Functional Restoration (IFR) P..H. Peckham Case Western Reserve University/FES Center, Cleveland/ UNITED STATES OF AMERICA Background: The Institute for Functional Restoration (IFR) was created within Case Western Reverse University (Case) to fulfill the mission of enabling the clinical deployment of new treatments to those with spinal cord injury (SCI) and stroke. Structured as a non-profit, the IFR incubates the proven feasible research interventions, like those in the Cleveland FES Center, through commercial approval and production. This research program has demonstrated clear clinical success with technology developed at Case, but like most products for SCI, has a small market size that has not been sufficient to attract and retain commercial interest at this stage. As demonstrated time and again, this neurotechnology makes real and extensive strides towards a true restoration of function for those that have been devastated by neurological conditions such as spinal cord injury. The ability of this technology to return functions lost, like the use of a hand or bladder control is proven. The desire of this patient population to undergo the implantation procedure in hopes of regaining some independence is proven. The support of this approach as the best, near-term clinical alternative by the top physicians in this field is established. Methods: Unlike many new companies, the technology, market and distribution channel are known and established. The barrier to commercializing these devices lies in the need to demonstrate high growth potential and large market sizes to satisfy early investment. Given that these devices will never reach thousands of units per year in a market size of hundreds’ of thousands, a new approach is being proposed that transcends the for-profit constraints and exists to make this life-changing technology available to hundreds of people with neural involvement. Key to achieving the overall project goal is the establishment of a practical and sustainable nonprofit deployment strategy. Given the high costs to achieve regulatory clearance and support a clinical distribution channel, versus the small market opportunity, a non-profit model can identify alternative revenue streams to mature the products and sustain a deployment strategy without achieving high unit sales. Results: Funded by a combination of revenue from products sold and supplemental grant and development funds, the IFR will ensure a long term commitment to bringing to market advanced technologies that transcends typical freemarket pressures. We will outline a strategy for creating a stable financial base in order to ensure the longevity of both the model and of the clinical and technical support for the individual users. As stated in recent comments from a reviewer for the Neilson Foundation, “to my knowledge this approach is unique and the whole world will be watching to see if it is found to be a successful way to break through the barriers of translating new medical technology”. References: Agarwal S. Long-term user perceptions of an implanted neuroprosthesis for exercise, standing, and transfers after spinal cord injury. Alon G..Persons with C5 or C6 tetraplegia achieve selected functional gains using a neuroprosthesis. Arch Phys Med Rehabil. 2003 Jan;84(1):119-24. Bryden AM. Electrically stimulated elbow extension in persons with C5/C6 tetraplegia: a functional and physiological evaluation. Arch Phys Med Rehabil 2000;81;80-88 P3-16 Identifying Quality of Life Outcome Tools for Measuring The Impact of Pressure Ulcers in Persons with Spinal Cord Injury S.L. Hitzig1, C. Balioussis1, B.C. Craven1, E. Nussbaum2, C. Mcgillivray1, L. Noreau3 1 , University Health Network, Toronto Rehab, Toronto/ON/ CANADA, 2, Mount Sinai Hospital, Toronto/ON/CANADA, 3, Centre for interdisciplinary research in rehabilitation and social integration (CIRRIS), Quebec/QC/CANADA Background: Pressure ulcers are a frequently occurring secondary health condition in persons with spinal cord injury (SCI) which negatively impacts a person’s quality of life (QoL) because of their potential to interfere in physical, psychological, and social domains [1]. Unfortunately, our understanding of how to assess QoL post-SCI is confounded by conceptual and measurement issues [2], which makes it challenging to select an appropriate outcome tool. Hence, the purpose of this review was to identify the outcome measures used to assess the impact of pressure ulcers on QoL and social participation in order to enable selection of appropriate tools by SCI professionals in a variety of clinical and research settings. Methods: Electronic databases (MEDLINE/PubMed, CINAHL, and PsycInfo) using relevant keywords were searched for studies published between 1975-2011 (N = 71). Studies were included if 50% of the participants had traumatic SCI. Studies examining global constructs of QoL or participation after SCI and studies using paediatric populations (or pediatric-onset SCI) were excluded (n = 58). From the remaining thirteen studies, data were abstracted and then presented in summary tables outlining study design, participant demographics, objectives, QoL outcome measures, sample size, and study outcomes. Using Dijker’s [2] theoretical model of QoL, the underlying constructs for the identified outcome measures were described. Results: Identified studies utilized participant’s self-report regarding the occurrence and location of pressure ulcers except for one, which reported the presence and severity of the pressure ulcers using the clinical stages defined by the National Pressure Ulcer Advisory Panel. The domains of measurement identified from the subjective perspective (insider view) for assessing pressure ulcers included subjective well-being, social adjustment, and self-esteem. From the objective perspective (outsider view), the constructs of participation (involvement in life situations) and healthrelated QoL were examined. All of the measures identified demonstrated sensitivity to the presence of pressure ulcers in persons with SCI compared to those without pressure ulcers. The majority of tools do not have psychometric evidence supporting their use in the SCI population with the exception of the Short-Form 36, Craig Handicap Assessment and Reporting Technique, Life Situation Questionnaire-Revised, and the Ferrans and Powers Quality of Life Index SCI-Version. Several QoL and social participation outcome measures are sensitive to the presence of a pressure ulcer but only a few have been validated for use in SCI. A significant limitation is that all the studies, with one exception, did not collect or report the location or severity of the pressure uclers. Qualitative findings reinforced the notion that measures collecting information on social support and body self-esteem may be pertinent domains negatively impacted by pressure ulcers post-SCI. The Cardiff Wound Impact Schedule (CWIS) is emerging as a promising outcome tool for the SCI population for illustrating pressure ulcer impact, although further psychometric validation is required prior to routine implementation. References: 1. Regan M, et al. Pressure Ulcers Following Spinal Cord Injury. In Eng JJ et al., (eds). Spinal Cord Injury Rehabilitation Evidence. Version 3.0. 2010. 2. Dijkers MPJM. Individualization in quality of life measurement: Instruments and approaches. Arch Phys Med Rehabil 2003;84:S3-S14. 79 P3-17 Spinal Cord Injury Quality of Life Instruments: Do They Measure What They are Supposed to Measure? K. Boschen1, T. Jeji2 1 , University of Toronto, Toronto/ON/CANADA, 2, Ontario Neurotrauma Foundation, toronto/ON/CANADA Background: Although researchers and even the general public cannot agree on a common definition of quality of life, a review of empirical investigations and theoretical discussions suggests that two major approaches to studying QOL are currently utilized. The first focuses on objective QOL, defined as the sum total of desirable possessions, traits, and statuses, such as having a good job, a high income, a clean and safe community to live in, good health, and a supportive family and friends. Once measured in quantitative terms scientists realized that objective characteristics (level of education, annual income, crime rate of one’s city of domicile) do not necessarily correspond to subjective experiences, thus the study of individual affect and cognition seemed imperative. The focus on subjective QOL commonly refers to social, psychological, and/or subjective well-being (Duggan & Lysack, 1999). A spinal cord injury constitutes a significant challenge to quality of life. SCI affects, directly or indirectly, those aspects of life that have been defined by researchers to constitute QOL: health and personal safety, independence, the ability to earn an income, access to material comforts, the likelihood of developing a close relationship with a member of the opposite sex, the ability to have and raise children, and having a close and supportive network of friends. Body image, self-concept, and one’s understanding of self are also significantly affected, directly or indirectly. In a modification of specification provided many researchers subjective QOL can be defined as the fit between a person’s expectations and his/ her achievements, as experienced by the person, within a time perspective. (Dijkers,1987). A full understanding of quality of life measurement issues for persons with both a spinal cord injury and the challenges of having pressure ulcers requires investigation of available and potentially relevant existing QOL measures and the context in which they have been developed and used. Methods: Literature Critical Appraisal. Systematic online search and exploration of multiple electronic databases for all known QOL measures that could potentially be appropriate for use in research studies to assess change in QOL resulting from the having a SCI and develoing a pressure ulcer. Results: Discarding of non-relevant or non-applicable measures resulted in review of the following 6 existing QOL measures which were briefly examined and assessed for their suitability: 1. Life Situation Questionnaire--Revised (LSQ-R) 2. Ferrans and Powers Quality of Life Index SCI-Version III (QLI) 3. Reciprocal Social Support Scale (RSS) 4. Cardiff 80 Wound Impact Schedule (CWIS) 5. LISAT-11 (Life Satisfaction Scale) 6. World Health Organisation QOL Breif Though none of these measures are specifically developed for utilizing in QOL measurement in SCI they are objective measures of some aspects of life, activities and satisfaction in those areas of participation. References: Duggan, C. H. & Lysack, C. “Quality of Life for Persons with a Spinal Cord Injury: A Qualitative, Longitudinal Study”. Three-year field-initiated research grant funded (07/99) by the National Institute on Disability and Rehabilitation Research (#H133G990219). Dijkers, M. (1997). Quality of life after spinal cord injury: A meta analysis of disablement components. Spinal Cord P3-18 On a Roll: Creating a Provincial Action Strategy to Address Quality of Life Issues for People with Spinal Cord Injury H. Lissel, T. Clarke Canadian Paraplegic Association (Alberta), Edmonton/ CANADA Background: On a Roll and on the Right Track: the Alberta Spinal Cord Injury Action Strategy was created as part of the Alberta Spinal Cord Injury Initiative. In 2007, the Government of Alberta contributed $12 million to support this five-year initiative. Management was shared among the Rick Hansen Foundation, the Rick Hansen Institute, and The Alberta Paraplegic Foundation (APF). The Canadian Paraplegic Association (Alberta) provided secretariat support for the APF and the two advisory committees established by the APF to help direct use of the funds: the Alberta SCI Solutions Alliance and the Alberta SCI Research Team. On a Roll was created in response to the need to identify and take immediate action to address key issues affecting the quality of life of Albertans with SCI. It builds on the legacy of past strategic plans in both the SCI and disability fields. Where it differs is in the focus on delivering short-term tangible results in a small number of areas deemed by stakeholders to be priority. On a Roll is a call to action and a committment to produce. It defines the ‘right track’ towards improving quality of life outcomes for Albertans with SCI and ensuring that our collective efforts deliver the best results. It also serves as a model for future action in this important area. Methods: The following method was used to develop and implement On a Roll: 1. Conduct telephone interviews with individuals with SCI and other stakeholders from the field of SCI. 2. Review and analyze strategic plans and policies from relevant disciplines. Investigate best and promising practices in high needs areas (e.g. housing, home care). 3. Conduct a Delphi study with individuals with SCI and other stakeholders to create a prioritized list of needs of people with SCI. 4. Hold a Stakeholder Forum to review the draft strategy document and confirm priority needs. 5. Create three Task Teams in the highest ranked needs areas: housing, home care/attendant care, adaptive equipment/devices. 6. Task Teams create eight Action Plans to address issues in the three areas. 8. Create working groups to implement the Action Plans. 9. Implement Action Plans 10. Evaluate Results: The three task teams created eight Action Plans: 1. an online community resource guide 2. a community living attendant training program 3. a funding and outcomes tracking project for pressure relieving and reducing devices 4. six mobile adapted computer stations for trial use by people with SCI and other physical disabilities 5. a protocol paper, treatment algorithm, and consumer brochures on the topic of urinary tract infection 6. an evaluation of supportive housing models and development of a sample business case 7. an online accessible housing registry 8. a concept and framework for a builders’ award recognizing excellence in accessible home design and construction The process of developing and implementing On a Roll also serves as a valuable template for future endeavors. References: Alberta Spinal Cord Injury Initiative. (2010). On a Roll and on the Right Track: The Alberta Spinal Cord Injury Action Strategy. Edmonton: Canadian Paraplegic Association (Alberta). P3-19 Towards Interventions Focusing on Community Living and Quality of Life for Individuals with Spinal Cord Injury: The Com-Qol Team K. Boschen1, F. Routhier2, L. Noreau2, L. Beauregard2, S.L. Hitzig3, A. Latimer4, K. Martin Ginis5, K. Arbour-Nicitopoulos5, D. Kairy6 1 , University of Toronto, Toronto/ON/CANADA, 2, Centre for interdisciplinary research in rehabilitation and social integration (CIRRIS), Quebec/QC/CANADA, 3, Toronto Rehabilitation Institute, Toronto/ON/CANADA, 4, Queen’s University, Kingston/ON/CANADA, 5, McMaster University, Hamiltin/ON/CANADA, 6, Center for research in rehabilitation of greater Montréal, Montréal/QC/CANADA Background: Returning to community living is the expected outcome for most people with Spinal Cord Injury (SCI) after rehabilitation discharge. In 2007, the Ontario Neurotrauma Foundation (ONF) and the Quebec Rehabilitation Research Network (REPAR) jointly funded the COM-QoL Team with the goal of strengthening capacity and a culture of research collaboration between rehabilitation-based researchers in Quebec and Ontario working in the areas of Community Integration and Quality of life of individuals with SCI. In 2011, the funding of the team was renewed for a second round. The objective of this poster is to present process of building capacity among Ontario and Quebec SCI researchers and activities of the COM-QoL Team. Methods: The team has built their research program on the existing expertise of 9 university researchers, and also on the needs of their clinical collaborators. The team address issues/ interventions in the fields of physical activity, wheelchair skills, social support, participation/quality of life and pain management, while encouraging the development of new collaborations between senior and junior researchers, and between provinces. Knowledge translation and mobilization (KT/KM) is explored as a field of investigation on its own. When conducting specific projects, data collection is carried out in both provinces. Results: Participation in physical activity was assessed in 94 people with SCI (Quebec) in line with Ontario data already collected. Three-year follow-up is underway to support another physical activity study in Ontario. A Wheelchair Skills Program (WSP) infrastructure to train and assess SCI wheelchair users was implemented at the Toronto Rehabilitation Institute. We now aim to make the WSP content more accessible, in French and in English, and on a larger scale through workshop training sessions, web videos, etc. A social support project to family members of individuals with SCI led to the development of an intervention that will be tested in both provinces. A cooperative project with another team (SCI-IMPACT) has produced a set of guidelines for researchers and clinicians, available thought the Web (www.parqol.ca), to help them make decisions on which outcome tools should be used to assess QOL and participation. A process of assessing the extent of dissemination of the website and its ability to adequately inform about quality of life will be developed. We currently develop a pilot project to test a SCI-specific Pain Management Group manual and program developed in Toronto. Research activities specifically related to implementation science and KT/KM are conducted by our team members. COM-QoL projects are used as experimental cases. In conclusion, during 2007-2011, the COM-QoL Team has implemented projects, collected data, and transferred its expertise across Quebec and Ontario provinces. The 2011-2014 round of funding will strengthen the collaborations among researchers and clinicians. A key addition to COM-QoL work plan will be a focus not only on the utility and utilization of the outcomes and deliverables to come from each individual project listed, but also on an examination of the overall KT/KM achieved from our team’s accomplishments on behalf of individuals living in the community with SCI. References: No references. 81 P3-20 P3-21 Effect of Motor Score on Adverse Events and Quality Of Life in Patients with Traumatic SCI Investigating Life Satisfaction of Community-Dwelling Individuals Living with a Traumatic Spinal Cord Injury in Ontario, Canada— A Pilot Study J. Street1, V. Noonan2, C. Fisher3, A. Cheung2, B. Sun2, M. Dvorak1 1 , Vancouver General Hospital, Vancouver/BC/CANADA, 2, Rick Hansen Institute, Vancouver/BC/CANADA, 3, Vancouver General Hospital, Vancouver/CANADA Background: Neurological impairment associated with traumatic spinal cord injury (tSCI) results in significant health care costs and disability. If risk factors for poor patient outcome could be identified early in the process of care, appropriate measures can be put in place to improve outcome and reduce costs. The purpose of this study was to assess the impact of neurological impairment, specifically motor score on admission, on the incidence of adverse events, length of stay (LOS) and long-term health status in patients with tSCI. Methods: Patients with a tSCI discharged from a quaternary acute care centre between 2008 and 2010 were identified from our prospective registry. Adverse event data was prospectively collected using the previously validated Spine Adverse Events Severity instrument. Data related to patients’ injury, diagnoses, hospital admission, and follow-up Short Form-36 (SF-36) Physical and Mental Component Scores (PCS, MCS) were obtained from the registry. The five most common adverse events were identified and multivariate analyses were performed to determine whether the initial motor score on admission was significantly associated with each adverse event, as well as with LOS and SF-36 scores at 1 to 2 years post-injury. Results: 171 patients with tSCI were included, 81.3% were male and the mean age at injury was 47.2 ± 20.3 years. A lower motor score on admission was significantly associated with having pneumonia, pressure ulcers and urinary tract infections (p<0.05); no association was found with delirium or neuropathic pain. There was also a significant association between motor score and the incidence of adverse events and LOS (p<0.0001). For each 10 point decrease in motor score, LOS increased by 20%. In patients with a motor score over 50, the SF-36 PCS increased by 3.8% for each 10 point increase in motor score. There was no effect on the SF-36 MCS. These findings indicate that initial motor score can predict important outcomes such as incidence and types of adverse events, LOS and long-term health status. Patients with low motor scores should be identified on admission to maximize their health outcomes. References: Not applicable 82 S. Boulet1, L. Cremasco1, M. Finlay2, B. Drew2, D. Tsui2 1 , McMaster University, Hamilton/ON/CANADA, 2, Hamilton Health Sciences, Hamilton/ON/CANADA Background: There is an estimated 44,000 individuals living with traumatic spinal cord injury (SCI) in Canada.1 Studies investigating the quality-of-life (QoL) of individuals with SCI have found lower QoL compared to the general population,2,3 but no differences in QoL between people with tetraplegia versus paraplegia.3-5 QoL of individuals with SCI appear related to subjective perception of health, participation, community integration, relationships, social support, and living circumstances.6 In this population, decreased QoL has been correlated with presence of comorbidities,7,8 restricted social participation,8 and increased pain, spasticity, and bowel and bladder dysfunctions.2 The Rick Hansen SCI Registry (RHSCIR) is a Canadian database that store information about traumatic SCI. This pilot study aimed to use the RHSCIR in Hamilton, Ontario to 1) determine whether QoL is different between those with tetraplegia versus paraplegia, and 2) to investigate the association between QoL and participant characteristics in people with SCI who live in the community. Methods: This multicentre prospective cohort study recruited adult patients with traumatic SCI admitted to Hamilton Health Sciences from September 2006 to April 2010. Consenting participants who were discharged to the community and could be contacted were interviewed by phone from August 2007 to November 2008 and from February to March 2011. Information regarding sociodemographics, SCI characteristics, and QoL (using the Life Satisfaction-11 (LISAT-11) Questionnaire) was collected. Data analyses used the MannWhitney U test and Spearman’s rho correlation. Results: In this pilot study, 26 participants completed the community follow-up interview. QoL as measured by LISAT-11 average scores did not significantly differ between those with tetraplegia (4.1±1.2) and paraplegia (4.1±1.0) (p=0.608). LISAT-11 average scores significantly correlated with completeness of injury (r=0.509, p=0.008), employment status (r = 0.463, p=0.017) and financial assistance status (r = 0.450, p=0.021). References: 1. Farry A, Baxter D. The incidence and prevalence of spinal cord injury in Canada: overview and estimates based on current evidence. www.rickhanseninstitute. org. 2. Westgren N, Levi R. Quality of life and traumatic spinal cord injury. Arch Phys Med Rehabil. 1998;79:1433-1438. 3. Post M, Noreau L. Quality of life after spinal cord injury. J Neurol Phys Ther. 2005;29:139-146. 4. Post MWM, de Witte LP, van Asbeck FWA, van Dijk AJ, Schrijvers AJP. Predictors of health status and life satisfaction in spinal cord injury. Arch Phys Med Rehabil. 1998;78:395402. 5. Post MWM, Van Dijk AJ, Van Asbeck FWA, Schrijvers AJ. Life satisfaction of persons with spinal cord injury compared to a population group. Scand J Rehab Med. 1998;30:23-30. 6. Geyh S, Fellinghauer BAG, Kirchberger I, Post MWM. Crosscultural validity of four quality of life scales in persons with spinal cord injury. Health Qual Life Outcomes. 2010;8:94. 7. Koppenhagen CF, Post MW, va der Woude LH, de Groot S, de Witte LP, van Asbeck FW et al. Recovery of life satisfaction in persons with spinal cord injury during inpatient rehabilitation. Am J Phys Med Rehabil. 2009;88:887-894. 8. Barker RN, Kendall MD, Amsters DI, Pershouse KJ, Haines TP, Juipers P. The relationship between quality of life and disability across the lifespan for people with spinal cord injury. Spinal Cord. 2009;47:149-155. adaptations. Designing a dwelling with the needs of more persons in mind is not just a technical issue that we can deal with in the future; it is a creative act we consider now, so the future is better for everyone. P3-22 • designed to simultaneously satisfy users with varying disabilities. They provide on grade access, open floor plans, adjustable kitchen counters, lever door handles, accordion closet doors, adjustable rods and shelf heights, reinforcing for future installation of a stair lift, and grab bars, all to help individuals in wheelchairs. Housing for Everyone R. Wickman Ron Wickman Architect, Edmonton/AB/CANADA Background: Ron Wickman received his Master of Architecture at the Technical University of Nova Scotia in 1991. He set up his own Edmonton based practice in January 1995. Ron’s interests and expertise is in barrierfree design that is accommodating the needs of individuals with disabilities; he also has a special interest in multi-family housing and urban and community planning. He specializes in providing consulting services for persons with disabilities and for projects focused on affording individuals with disabilities greater choices for independent movement. He is responsible for over 100 new home or home renovation projects designed to accommodate residents with disabilities. He is also committed to providing affordable, accessible, and adaptable housing and has won several housing competitions. Two built projects include the Affordable Housing Demonstration Project, built in 1996 and initiated by the City of Edmonton Planning and Development Department and the Innovative Housing Committee; and the CMHC FlexHouse – Habitat for Humanity Project built in 1997. Ron has experience as an expert witness in cases involving persons with disabilities, and he has also been a guest speaker and participant in numerous session involving Barrier-Free Design, innovation housing, and urban and community planning. Methods: This presentation identifies alternative forms of housing to larger senior’s apartment buildings, senior citizens villages, and assisted living housing projects. Projects highlighted are designed to be flexible enough to easily adapt to a family’s future needs, thus affording a family the choice to grow old in the same home and in the same community; moving to a larger senior’s complex does not need to happen. The conclusion here is that good housing is designed in the beginning to allow for easier future changes, additions, and Results: As a result, participants will learn more about: • Universal Design and accommodating persons with disabilities. • Housing that is designed to be affordable and adaptable • Homes designed to allow for aging in place. • Small scale housing as an alternative to larger scale senior’s developments. References: Innovative housing projects that I have recently completed in Edmonton, Alberta. All of the Projects are: • located in an inner city community so residents may be afforded a better access to a greater host of the neighbourhood amenities; inner city development promotes a safer and more positive and efficiently run city. P3-23 Translation, Transition, & Transformation—Mental Health for Persons with SCI, Families, and Care-Givers B. Williams Pacific Institute, Richmond/BC/CANADA Organization overview: This presentation will focus on the curriculum development of DISCOVERING THE POWER IN ME - CREATING A FUTURE OF STRENGTH AND HOPE in British Columbia, program applications, and the applied research results for persons with SCI by the University of B.C., University of Toronto, University of Western Sydney (Australia) , and current evaluations underway in Canada. Two of the research projects were approved for funding by the Rick Hansen Institute. The results of the applied research in three provinces in Canada and three states in Australia will include a focus on the mental health and psycho-social benefits to persons with SCI, family members, and care-givers drawn from both scientific surveys and consumer data. The methodology and the use of peer counsellors with SCI both on screen and in the group setting to facilitate and enhance the classroom experience of the curriculum will be highlighted. 83 The program was designed by persons with SCI who identified what they called the missing pieces on the ‘continuum of care’ both from their personal experiences and from their work with organizations assisting persons with SCI through difficult life transitions. The design team worked closely with the Pacific Institute to guide the development of the program. Disclosure: As Global Managing Director for the Pacific Institute I do have an indirect financial interest but I do not have control over the educational content which is owned and has trademark protection over it. The presentation will include both scientific findings as well as actual feedback on the two day program’s efficacy from participants in Canada, U.S., and Australia . P3-24 Background: Persons with spinal cord injuries often face significant psycho-social challenges in coping, adjusting, and moving forward to a positive and contributive future. To address these issues, a design team composed of persons with SCI from British Columbia and Alberta was formed to work with the Pacific Institute to identify ‘missing pieces’ in the continuum of care which , when addressed, might achieve the dual goals of: reducing the depths of despair following the injury and through support reduce the amount of time to successfully transition to a ‘new normal’ . The goal was to translate the best of cognitive psychology and social learning theories into accessible, clear concepts and relevant skills to support difficult transitions and to help create positive transformations in persons with SCI their families and care-givers. Building hope, strength, resiliency, self-esteem, and raising self-efficacy creates new confidence to self manage and design a new future. Methods: Since the design, development, and launch of the program Discovering the Power in Me - Building a Future of Strength and Hope, considerable field experience has been gained in Canada, U.S., and Australia with the SCI population and with other populations. The method includes providing a two day curriculum broken into 12 modules in which participants experience classroom experiences including : video clips presenting specific themes introduced and summarized by a person with SCI along with personal insights, in class co- facilitation which includes a person with SCI, reflective questions, individual & small group exercises to expand and anchor the concepts drawn from the significant works of Dr. Albert Bandura. Scientific research using peer reviewed surveys and evaluative questionnaires have been conducted in Canada, U.S., and Australia....two of which were funded by the Rick Hansen Institute. Results: The presentation will discuss the research findings conducted by the University of British Columbia, the University of Toronto, and the University of Western Sydney and other early evaluative data on both quality of life and transition to employment. References: and hand-out materials will be provided at the time of the presentation. 84 Altering Inflammation After Spinal Cord Injury Using Biomaterials Hong Ying Lia, Yue Zhoua, Paul D. Daltona,b Med-X Research Institute, Huashan Lu 1954, Shanghai Jiao Tong University, Shanghai, China. b Institute of Health and Biomedical Innovation, 60 Musk Ave, Brisbane, Australia. a Background: SCI repair is resistant to therapies due to the complex inflammatory reaction and inhibitory factors to regeneration [1]. There are diverse approaches SCI treatment, including drug/gene delivery, cell transplantation for both regeneration and neuroprotection. One field of research not widely used within SCI repair is materials science yet it has many forms – from injectable hydrogels to nanoparticles, porous scaffolds to nerve guides [2]. The past decade has seen an unprecedented expansion in the development of biomedical materials with new forms and functions [3]. In this context, we describe a fundamental aspect of material use within the spinal cord; analysing the injury parenchyma of a biomaterial implanted within the spinal cord. Since biomaterials are known to reduce the extent of secondary injury, we investigate how implanting a foreign body (material) could affect and alter the inflammatory cascade after SCI. This study compares short time points to gather insights into the innate immune reaction associated with implanting a foreign material into the spinal cord. Methods: A porous biomaterial (pHEMA) was implanted within the spinal cord of Male Wistar rats T7/8, into small lesions of either the posterior horn or dorsal funicular. The animals were perfused after 1 to 14 days and excised spinal cord tissue used for immunohistochemistry or quantitative PCR. Results: The injuries were reproducible and the pHEMA fitted well into the lesion. The recruitment of neutrophils was rapid and after 24 hours the biomaterial was filled exclusively with these cells. Activated macrophages migrated into the biomaterial and injury parenchyma after 3 to 6 days. In grey matter implants, surviving neurons (NeuN) are seen near the scaffold even after 14 days, indicating minimal secondary injury. While similar numbers of neutrophils and macrophages infiltrate the injury parenchyma for both the lesion and biomaterial, a higher gene expression of TGF-β after occurs with pHEMA implants in both the white and grey matter after 6 days. TGF- β is recognised as an important (anti-)inflammatory mediator in this injury scenario, and influences the remodelling of ECM after SCI [3]. Future work involves modifying the surface of the biomaterial to alter both the inflammatory cascade and regeneration, as well as using nanotherapeutics for similar inflammatory mediating purposes. Acknowledgements: The Natural National Science Foundation of China supported this research (#30970727). References: [1] Dalton PD, Harvey AR, Oudega M, Plant GW (2008) Tissue Engineering of the Nervous System, in Tissue Engineering. C Van Blitterswijk, Sohier (Ed.) Academic Press. p611-647. [2] Tsai E, Dalton PD, Shoichet MS, Tator CH (2004) J Neurotrauma, 21, 789-804. [3] Dalton PD, Mey J (2009) Front Biosci, 14, 769-795. [4] Hall et al. (2004) J Neurosci Res, 76, 1. 85 Author Index Afram B. Ahn H. Al-Yahya A. Albert M. Allan D. Allen V. Allison D. Alton C. Ansley B. Arbour-Nicitopoulos K. Arndt A. Asiri Y. Assinck P. Athanasopolous P. Atkins D. Badley E. Bailey C.S. Bain P. Balioussis C. Bank M. Barrable B. Batke J. Bauman, W. Bayless K. Beaton D. Beauregard L. Bedard F. Berlowitz D.J. Berube M. Beynon M. Beynon M.E. Biering-Sørensen F. Birnböck D. Bjerkefors A. Bloom O. Boily K. Borisoff J. Boschen K. Bosma R. Bosma R.L. Boucher N. Boulet S. Bourassa-Moreau E. Bourassa-Moreau Boutin N. Brenner R. Brinkhof M.W.G. Bronson R. Brown D.J. Brown J. Burns A. Cadotte D. Cameron P. Campbell K. 86 45 41, 54 47 73 60 37 69 60, 61 36 81 55 47 71 66 64 63 41 44 50, 79 25 72 35 14 76 63, 34 53, 81 73 55 73 69 32, 70 9 67, 67 55 25 39 74 54, 80, 81 25 69, 70, 32 53 82 64 33 73 31 56 72 55 58, 76 58, 41, 57 25, 26 55 32, 42 Cartar L. Carter P. Chakraborty S. Chan A. Chan B. Chauny J.-M. Chen Y. Cherban E. Cheung A. Cheung C. Cheung K. Clarke C. Clarke T. Claydon V. Codyre M. Connolly S. Contandriopoulos D. Conway B. Cragg J. Craven B.C. Craven C. Cremasco L. Cui J.-L. Curt A. Czajka T. Dai H. Dalton P. Delisle S. Desjardins P. Desroches G. Devivo M. Ditor D. Dobek C.E. Domingo A. Drew B. Drouin K. Duda M. Dupuis A. Dusablon A. Dvorak M. Elliott S. Eng J. Ethans K. Fawcett J. Fehlings M. Fehlings M.G. Finlay M. Fisher C. Flett H. Foley N. Fourney D.R. Francis C. Fransen B.L. 38 37 77 54 58 73 37 50, 38 66, 82 31 51 60 80 13, 62, 65 43 51 73 60 74 63, 34, 36, 79, 41 50 82 70 15, 22, 34, 36 66 72 84 73 29 29 37 69 32, 69, 70 31, 47 36, 82, 41 59 76, 58 58 73 23, 63, 64, 66, 35, 72, 82, 38, 41 8 47, 51, 68, 39 52 8 24, 78 8, 21, 25, 26, 64, 34, 41 82 66, 82 57, 58, 32, 34 52 41 45 71 Frazier B. Frieden L. Furlan J.C. Gabriel D. Gagne A. Gagnon D. Galen S. Gan L.S. Ghag A. Gignac M. Goldstein B. Goss B. Goudie C. Gourdou P. Graco M. Grangeon M. Green L. Gregorini F. Grossman, R. Guindon A. Guest, J. Guy K. Hallgrimsson B. Hamdani Y. Hammond M. Harkema S. Harder E. Harrop J. Haycock S. Hayes K. Hendricks R. Henry J.L. Hicks A. Hill D. Hill T. Hilton B. Hitzig S.L. Hodgkinson N. Hoffer A. Hong Y.L. Horsewell J. Houghton P. Hsieh J. Hu Y. Huitsing C. Hunter J. Illes J. Inglis G. Inskip J. Jeanmaire C. Jeji T. Jetha A. Joly C. 37 P3-15 40, 78 69 73 29, 59 60 30 23 63 37 27 74 29 55 59 69 67, 67 15 53 15, 21 34 74 62 37 17 28 12 44 10 37 44 27, 29 52 48 71, 23 81, 44, 58, 60, 61, 79 76 45 84 43 42 50, 51, 51, 52, 58, 32, 76, 39 70 76 44 23 69 62 43 44, 52, 66, 50, 80 62, 63 47, 58 Jones G. Joshi P. Kairy D. Kalke Y.B. Kalsi-Ryan S. Kenneth G. Kessler T. Kim A. Kirshblum, S. Knox J. Koning C. Kozomara M. Kras-Dupuis A. Krassioukov A. Krueger H. Kurzweil R. Kwon B.K. Lacroix S. Laflamme E. Lam C.K. Lam T. Langer R. Laramée M.-T. Latimer A. Lawrence M. Lear S. Leber D. Lebkowski J. Leblanc K. Lee J. Lee J.H.T. Lee S.S. Lefebvre H. Legg A. Leong N. Lewis R. Li X. Liang J. Linassi A.G. Lindberg T. Lissel H. Liu J. Liu Q.Q. Loh E. Luk K.D.-K. Lutton C. Mac-Thiong J.-M. Macgillivray M. Mackay-Sim A. Macrae L. Macthiong J.-M. Manocha R. Marinho A. Mark M. 27 63, 72, 41 81 31, 49 34 16 67, 67 54 18 58 32, 76 67 50, 32 7, 13, 19, 65, 68, 40 63 17 14, 23, 62, 35, 71, 41 73 73 71 47, 28, 31 72 47 29, 81 72 65 57 17 66 52 71 28 53 26 60, 61 64 70 31 41 55 80 71 26 52 70 27 59, 33, 64 46 27 66, 36 73 46 34 76 87 Martin Ginis K. Matheson K.A.J. Mattison C.A. Mcgillivray C. Mcgrath M. Mcinnes C. Mcintyre A. McKerracher L. Mclean A. Mcmillan C. Mehnert U. Mehta S. Mendis B. Meyyappan R. Mikulis D. Miller W. Miller W.C. Milligan J. Mittmann N. Moore A. Morris H. Mumme L. Nadeau S. Nasirzadeh Y. Nassiri F. Nguyen L. Nguyen T. Noonan V. Noreau L. Norrbrink C. Nussbaum E. O’Connell C. O’Connor T.P. Oliver D. Onders R. Orenczuk S. Panjwani A. Papatheodorou A. Parent S. Park S.E. Parmar R. Pauhl K. Peckham P..H. Pelletier C. Phillips A. Plunet W. Popovic M. Price D. Pritchard C. Prochazka A. Prud’Homme Lemaire M.-C. Rajamanickam K. Ramer M. Raschid A. Rasheed A. Ravensbergen R. 88 11, 81 71 44 79 62 54 51, 52 9, 16 60 52 67, 67 49, 51, 51, 52 77 45 25, 26 51 68, 40 52 58 66 34 76 29 24 24 57 77 50, 63, 66, 35, 72, 82, 38, 41, 39, 64 10, 79, 53, 81 55 79 41 26 66 39 49 25, 61 25 59, 64, 33, 73 71, 39 48 28 18, 78 27, 29 21 71, 74 29, 34, 34 66 72 17, 30 73 77 74 50 58 65 Ravid E.N. Reichel H. Reynolds F. Reynolds S. Richardson J. Riopelle R. Rivers C. Robidoux I. Routhier F. Roy B. Rupp For The EMSCI Study Group R. Sahota I. Sakakibara B.M. Salter K. Sandoval R. Santos A. Satkunendrarajah K. Saunders N. Sawatzky B. Schubert M. Sci Kmn Sci Kmn Team S. Scovil C. Shantharam Y. Shin J. Short C. Sihota H. Sinclair S. Singh A. Sinnott R. Sison C. Slotkin J. Smith M. Soril L. Spungen, A. Stein A. Stoesz B. Street J. Streijger F. Stroman P.W. Sullivan D. Sun B. Tam V. Taunton, J. Teasell R. Teng Y. Tetzlaff W. The Scire Research Team -. The Swisci Study Group &. Thompson C. Thorogood N. Tindale L. Townson A. Trenaman L. Truchon C. Tsai E. Tsui D. 30 49, 31 72 45 66 58 63, 38 59 81 69 36 65 51, 40 51 45 64 24 60, 61 46 36 47, 57 32 57 44 54 51 43 66 64 55 25 72 43 64 19 25 58 66, 82 71 25, 32, 69, 70 43 66, 82, 38 58, 47 20 49, 51, 51, 52 72 9, 22, 23, 23, 71 40 56 64, 33 72, 39, 41, 35 45 51, 54 63 58 41, 77 36, 82 Tung K. Uleryk E. Ullrich P. Vermette M. Verrier M. Von Elm E. Wahman K. Wakeling J. Walden K. Walter M. Wang W. Warburton, D. Warner F. Wecht J. Wen C.-Y. West C. Wickman R. Wilcox J. Williams B. Williams J. Williams R. Williams S. Wirth E. Wojkowski S. Wolfe D. Woodard E. Wright P. Wöllner J. Wong S. Wyndaele, J. Young W Young Y.W. Yu D. Zander J. Zbogar D. Zhou M. Zhou Y. 54 44 37 29 50, 68, 34, 36, 34 40 55 28 38 67, 67 26 19 74 13 70 20 83 24 54, 83 34 27 11 16, 72 66 50, 51, 51, 52, 58, 39, 32 72 58 67, 67 21 7 12 27 72 38 68 7 84 89