J. Crayton Pruitt Family DEPARTMENT OF BIOMEDICAL
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J. Crayton Pruitt Family DEPARTMENT OF BIOMEDICAL
J. Crayton Pruitt Family Department of Biomedical Engineering J. Crayton Pruitt Family Department of Biomedical Engineering Biomedical Sciences Building | Room JG56 | P.O. Box 116131 | Gainesville, FL 32611-6131 P 352.273.9222 F 352.273.9221 www.bme.ufl.edu Welcome from the Chair T BME Undergraduate Program he J. Crayton Pruitt Family Department of Biomedical Engineering has come a long way in the ten years since it was launched in 2002. The department has grown to 16 faculty, one instructor, six research faculty, nearly 50 affiliate faculty, six staff members, 20 undergraduate and over 140 graduate students. We have graduated 171 M.S. and 76 Ph.D. students, received over $26M in external research funding and published more than 300 peer reviewed scientific papers. In 2009 the Department moved into the brand new Biomedical Sciences Building located in the University of Florida Health Sciences complex and only a very short walk to engineering. In all we have a great start and are well-poised for another period of growth and excitement. The J. Crayton Pruitt Family Department of Biomedical Engineering is proud to have started its undergraduate BME degree program this fall, with its first class of 20 exceptional students. The program is scheduled to grow to 70 students per year so as to help fulfill the tremendous demand at UF and to help keep in Florida many students who would otherwise leave the state for a BME degree program. Demand is growing, as industry, graduate and professional schools recognize the value of ambitious students who have come with the intellectual approach of a well-trained engineer yet are well informed as to basic physiological and biomolecular science. To accomplish this, Department faculty are collaborating with other engineering and life science departments for courses, especially in the short run, anticipating further development of much more integrated BME courses. BRIGHT FUTURES FOR BME New Building for BME We are most excited that Dr. Christine Schmidt will join the BME Faculty in January 2013 as Department Chair. She comes to us from the University of Texas at Austin, with an exceptional record in all of teaching, research, and service, having contributed substantially to that department’s rapid growth to national prominence. Dr. Schmidt has ambitious plans to increase the faculty size to over 20, grow research activity substantially, and raise the visibility of the UF BME Department. She sees the tremendous opportunities available due to the proximity of the UF Health Sciences and the entrepreneurial spirit that pervades Gainesville. PRUITT LEGACY The Department owes its success to the J. Crayton Pruitt Family, for their endowment of the department with a $10M gift which was matched by the State of Florida. The gift has since been augmented by the Pruitt Family with funds for endowed professorships. We note the passing last year of our benefactor, Dr. J. Crayton Pruitt, Sr. Among all the other amazing things he accomplished was the invention of a biomedical engineering device – the very successful Pruitt-Inahara Shunt for cardiovascular surgery. Dr. Pruitt showed great interest in all aspects of the department, including very obvious excitement for novel research performed by individual faculty. The Pruitt Family legacy has enabled all of us – new faculty and students especially – to prosper in this great field. The Department occupies 18,000 square feet of excellent research space, and 27,000 square feet overall, in the new Biomedical Sciences Building, which is located on medical campus and is shared with the College of Medicine. This will suffice for a portion of our planned expansion. The department’s medical physics faculty have separate offices and facilities in the Nuclear Sciences Building, which is also home to our undergraduate laboratories. understanding the interplay of materials with the immune response, magnetic biomaterials, novel materials for cardiovascular and neural system applications, and to study degenerative joint diseases. Faculty affiliates are involved in a much broader array of interests, including biomaterials, drug development, biomechanics, orthopedics, rehabilitation engineering, MR imaging, and computational bioengineering. Overall we are developing strong collaborations with our sister engineering departments and multiple departments in the Health Sciences. Faculty affiliates are involved in a much broader array of interests, including biomaterials, drug development, orthopedics, rehabilitation engineering, MR imaging, and computational bioengineering. LOOKING FORWARD It has been an honor to have served as Acting Chair for nearly four years and especially to have seen tremendous growth in the department. I look forward to the even greater excitement and progress that is to come. We truly are carrying out Dr. Pruitt’s vision as we pursue Excellence in Biomedical Engineering Education & Research to Improve Human Health Sincerely, RESEARCH EXPERTISE Bruce C. Wheeler, Acting Chair The Department has several exceptional areas of expertise. Perhaps the largest area is neural engineering, which engages six of our principal faculty and a number of our affiliates. The expertise includes computational, recording and imaging Christine E. Schmidt, Chair (1/1/2013) technologies for understanding cognition and pathologies in humans; microfabrication technology for controlling cultured neural networks; neural stem cell engineering and innovative biomaterials for BME FACTS neural growth. Optical imaging is a real strength, with em1. Largest and most comprehensive BME department in Florida phases on photoacoustic tomography for several medical applications including breast cancer. 2. One of a very few BME departments in the nation to be co-located Medical physics faculty are active in the areas with a medical college. of dosimetry and PET imaging, including computational approaches. 3. Basic and applied research tackles medical problems; spinoffs provide cost-effective health care delivery. Overlapping faculty interests in biomaterials , tissue engineering, and biomechanics 4. Rapid increase in research funding makes UF BME competitive provides a growing substrate for research into 3 KYLE ALLEN Assistant Professor Ph.D. 2006, Rice University Degenerative Joint Diseases Osteoarthritis Biomechanics Gait and Locomotion Biomarkers degenerative joint diseases D egenerative joint diseases include osteoarthritis, degenerative disc disease, and other pathologies that destroy articulating joints. In degenerative joint diseases, cartilage is slowly destroyed, leading to joint pain and disability. These diseases are classically described by the severity of cartilage loss; however, recent work has evolved to think of the joint as an organ, examining the interplay between cartilage, bone, ligament, tendon, and synovial tissues. Our laboratory embraces the ‘joint as an organ’ approach, aiming to identify changes in the joint biology and mechanics that ultimately lead to pain and disability. LINKING DISEASE MEDIATORS TO PAIN AND DISABILITY T reatment of osteoarthritis (OA) raised 2007 US healthcare expenditures by $185.5 billion. In addition, the average annual out-of-pocket expense for an OA patient is nearly equivalent to 3 weeks pay for an average American. Despite this immense socioeconomic burden, OA therapies have been difficult to translate from the lab to the clinic. While the primary reasons OA patients seek treatment are pain and disability, the symptomatic consequences of OA are not always evaluated in preclinical OA models. Thus, preclinical studies centered on structural changes alone may not identify diagnostics with the potential to predict OA-related pain and disability, nor identify therapeutics and interventions with the potential to reduce disease symptoms. Our laboratory has developed new methods to measure OA related pain and disability in rodent OA models. Our gait analysis methods (Figure 1) are capable of detecting compensations that are not visible to the human 4 eye. We are currently developing new behavioral methods to assess TMJ pain and dysfunction in rodent models of TMJ disorders. Using these new behavioral analyses, we hope to develop a new understanding of the relationship between disease mediators and the development of pain and disability, as well as new OA diagnostics and therapeutics. Figure 1: Image of our dynamic gait arena. Force plates are embedded in the floor of the arena that record ground reaction forces as a rodent walks across the arena MAGNETIC COLLECTION OF OA BIOMARKERS Clinically, degenerative joint diseases are diagnosed through radiographs and physical exams. However, these diagnostics are relatively poor at detecting early-stage OA, a stage where interventions are likely to have a higher success rate. A need exists for technologies that facilitate early OA diagnosis. The OA research community has recently placed a special emphasis on the development of OA biomarkers, diagnostics that can identify OA disease processes before traditional radiographs. Promising OA biomarkers have been identified in urine and serum. However, serum- and urine-level biomarkers are not specific to an affected joint, are likely dilute relative to levels in the affected joint, and may not be detectable at the earliest stages of OA. In collaboration with Dr. Jon Dobson and Dr. David Arnold, our laboratory recently developed new techniques to remove OA biomarkers and disease mediators from the joint space without the need to remove the synovial fluid that lubricates and supports joint function (Figure 2). We are also investigating new techniques to evaluate synovial fluid mechanics with Dr. Carlos Rinaldi. Figure 2: Fluorescent, magnetic particles collecting on the tip of a magnetic probe CELLULAR THERAPIES FOR DEGENERATIVE DISC DISEASE In the US, low back pain is 2nd only to flu and cold symp- toms on the list of reasons why patients schedule doctor visits. While back pain is often characterized by acute episodes, approximately 14% of the population will experience back pain lasting more than 2 weeks. Lumbar disc degeneration, or degenerative disc disease, is strongly implicated as a source of chronic low back pain. In addition to our work linking disease biology to pain and disability, our laboratory is developing new cellular therapy methods to treat degenerative disc disease. During intervertebral disc degeneration, the number of notochordal cells in the intervertebral disc decreases. Notochordal cells are a population of stem cells that is believed to help support and protect the cells of the intervertebral disc. In collaboration with Dr. Brian Harfe, our laboratory is investigating new techniques to isolate and culture populations of notochordal cells, with the hopes of developing cellular therapies for disc degeneration in the future. Figure 3: Clusters of mouse notochordal cells on a decellularized porcine nucleus pulposus Wesley BOLCH Professor Ph.D. , 1988, University of Florida Radiation Dosimetry Computational Phantoms Dosimetry Models of the Skeleton Computed Tomography Interventional Fluoroscopy Nuclear Medicine Radiotherapy Homeland Security Radiation Dosimetry R adiation dosimetry encompasses the calculation and measurement of energy deposition within the human body resulting from exposure to radiation sources at the workplace, in the environment, or from medical applications to imaging or cancer therapy. These exposures may result from either radiation sources external to the body (e.g., CT imaging) or internal to the body (e.g., radiopharmaceuticals). In most instances, radiation doses to the internal organs and tissues is nearly impossible to directly measure, and thus computational simulations of radiation transport and energy transfer are required using either patient or individual specific anatomical models, or computerize replicas of patient anatomy. COMPUTATIONAL PHANTOMS The Advanced Laboratory for Radiation Dosimetry Studies (ALRADS) at the University of Florida is a world leader in the development of hybrid computational phantoms of human anatomy – based upon the application of polygon mesh and NURBS surface modeling of internal organs and the outer body contour. A series of reference (50th percentile) models of the newborn to 15-year adolescent were developed at UF and recently adopted as international standards by the International Commission on Radiological Protection (ICRP). Other work has resulted in a 400+ member phantom library covering pediatric and adult males and females representing the current height/weight distribution of the US population. These phantoms are serving as the basis for pre-computed dose libraries for a broad range of medical imaging modalities – CT, fluoroscopy, and nuclear medicine. Other work has resulted in some of the most detailed anatomic models of developing embryo, fetus, and pregnant female for applications to both environmental and medical dose assessment. DOSIMETRY MODELS OF THE SKELETAL TISSUES The hematopoietically active tissues of bone marrow are the most radiosensitive tissues in the human body. At low radiation doses, exposure can increase the risk of leukemia induction, while at high doses – such as during radionuclide therapy – marrow suppression and toxicity may result. Predictive models of radiation dose to bone marrow are exceedingly difficult to develop owing to the complex microstructure of trabecular spongiosa, variations in marrow cellularity, and variations in bone mineral status of the individual or patient. UF has pioneered the use of CT and microCT imaging of human cadaveric bone to the application of radiation transport simulation and predictive models of marrow dosimetry. MR techniques for non-invasively assessing marrow cellularity have been developed and validated in a canine model. Skeletal models have been developed for both adults and pediatric phantoms, as well as the developing fetus. APPLICATIONS THERAPY TO MEDICAL IMAGING APPLICATIONS TO EPIDEMIOLOGY & HOMELAND SECURITY The computational models developed at UF have also been applied to studies of the Southern Urals populations exposed to radionuclides released during past USSR nuclear weapons development in the 1950s. These studies will significantly enhance our understanding radiation risks. Work at UF has also resulted in the development of computer software to assist first-responders in performing radiological triage of victims following radiological terrorist events. Share identical anatomy except gender organs AND The ALRADS laboratory is actively engaged in the development of predictive models of patient radiation dose for all major forms of diagnostic medical imaging. UF is working with the National Cancer Institute to develop software to predict organ doses to patients undergoing computed tomography imaging, including those scanned under tube current modulation. UF is also developing real-time software to predict and map skin dose to patients undergoing fluoroscopically-guided interventions, and to report organ doses using cloud-computing radiation transport simulation. Finally, UF is a key partner in national efforts to optimize the quantity of radiopharmaceuticals given to pediatric patients that will maximize image quality while minimizing risk of second cancers. In radiation therapy, the ALRADS laboratory has partnered with Oraya Therapeutics, Inc. to develop a noninvasive x-ray treatment for age-related macular degeneration. Newborn 1-year 5-year 10-year 15-year male 15-year female 5 Mingzhou Ding J. Crayton Pruitt Family Professor PhD., 1990, University of Maryland Neural engineering Cognitive neuroscience Signal processing Dynamical systems and neural modeling O ur long-term research objective is to understand the neural basis of higher brain functions and their impairments by neurological and psychiatric disorders. In particular, applying quantitative engineering approaches to multimodal neural data, including single unit spike train, multiunit activity, local field potential, electroencephalogram, electrocorticogram, and fMRI data, we address fundamental questions in the dynamic organization of brain networks and its disruption in disease. A theoretical framework, which integrates human physiology, monkey physiology, and computational modeling, is formulated to interpret the findings. Some specific areas of interest are as follows. Analyzing information flow in neuronal networks: Multielectrode neurophysiological recording and functional brain imaging produce massive quantities of data. Multivariate time series analysis provides the foundation for analyzing the patterns of neural interactions in the data. Neural interactions, being mediated by the synaptic transmission of action potentials, are directional. Our ability to assess the directionality of neural interactions and information flow in brain networks holds the key to understanding the cooperative nature of neural computation. Research over the last few years has proven that Granger causality is a statistical technique furnishing this capability. Our lab has pioneered the application of Granger causality to neuroscience. Recently completed projects using the technique include: (1) laminar organization of alpha oscillations in primate visual cortex, (2) functional characterization of beta oscillations in a large-scale network in sensorimotor cortex, (3) top-down control of visual and somatosensory processing by the frontal-parietal attention network, and (4) memory-modulated directional interaction between frontal and medial-temporal lobes. Single trial analysis of event-related signals: Neural data following the onset of a stimulus is comprised of an event-related 6 Network organizations of alpha oscillations in visual cortex revealed by current source density analysis (left) and Granger causality (right). Arrows represent directions of information flow. Cognitive brain machine interface: Brain machine interface (BMI) enables direct communication between the brain and an external device. While BMI research has been mainly focused on improving sensory-motor functions of paralyzed individuals, the same concept can be exploited to augment human cognition. Based on our recent physiological and methodological advances, a closed-loop cognitive brain machine interface (cBMI) is being designed and implemented, in which the stimulus presentation is conditioned on the occurrence of optimal brain states and the stimulus evoked response, separated from ongoing neural activity, is classified by machine learning methods. Electrode arrays implanted over the cortex of three epilepsy patients undergoing evaluation for surgical therapy (left). Information flow patterns between prefrontal cortex (PFC) and medial temporal lobe (MTL) during recall of memory and during baseline . component that is relatively time-locked to stimulus onset and ongoing brain activity. These two types of signals, generated by possibly different neural mechanisms, may reflect different aspects of cognitive information processing. In collaboration with colleagues in the College of Engineering and from other institutions, we have developed methods capable of separating the two signals on a trial-by-trial basis. These methods are being used to answer questions in areas ranging from network basis of decision-making to improved target detection in cognitive brain machine interface to determination of the time course of emotional conditioning. Studies of translational relevance: New discoveries are being made constantly in basic science labs around the world. How to translate our growing knowledge into improved healthcare is a critical issue facing today’s biomedical researchers. We are working with physicians and clinical scientists to address problems in the following areas: (1) effect of anticonvulsant drugs on language production and executive control of brain function, (2) disruption of cortical and subcortical network dynamics in depression and obsessive compulsive disorder, and (3) cognitive fatigue in Parkinson’s disease. JON DOBSON Professor & Director, Institute for Cell Engineering and Regenerative Medicine, ICERM Ph.D. 1991, Swiss Federal Inst. of Technology, ETH-Zurich A B C D Magnetic Biomaterials Nanomagnetic Gene Transfection Nanomagnetic Cell Actuation Brain Iron and Nerodegeneration E F G H I J K L T he main focus of our group falls into several interrelated categories as outlined below. The underlying theme of all this work is the novel use of magnetic nanoparticles to develop technologies for bionanotechnology/ nanomedicine applications in fields as diverse as gene therapy, stem cell therapy, tumour targeting and tissue engineering/ regenerative medicine. In addition, we have been developing synchrotron x-ray and MRI-based techniques to exploit naturally occurring magnetic iron oxides in the brain for diagnostic and mechanistic studies of neurodegenerative diseases, such as Alzheimer’s and Parkinson’s. Nanomagnetic Actuation: tissue engineering and stem cell therapy Magnetic nanoparticles are being used to target and manipulate cellular processes and functions and to control stem cell differentiation, primarily through the activation of ion channels. These nanoparticles are coated with a functionalizable polymer to which surface antigens/targeting molecules may be bound. These antigens may target either specific ion channels, such as the mechanosensitive TREK-1 potassium channel, or non-specific cell surface receptors such as integrins. By applying a static or time-varying magnetic field, forces exerted on the particles activate either specific ion channels or general membrane and cytoskeletal deformation activates adjacent mechanosensitive ion channels, initiating biochemical processes within the cell. We have used this technology to speed up bone matrix production, to control the differentiation of stem cells without chemicals, and to enhance production of cartilage and upregulate cartilage-related genes both in vitro and in vivo. These devices, Magnetic Ion Channel Activation (MICA) systems are being commercialized by a spinoff company. HBMSC HBMSC + TGFβ3 HBMSC + TREK-K+ HBMSC + RGD Histology and immunohisto-chemistry of HBMSCs only; HBMSCs and transforming growth factor b3; and HBMSCs labeled with TREK-1 or HBMSCs labeled with RGD particles encapsulated into alginate/chitosan capsules, implanted subcutaneously in MF-1 nu/nu mice, and exposed to a magnetic field for 21 days, 1 h/day (Mon., Wed. & Fri.). Representative 6 mm tissue sections stained for Alcian blue/Sirius red (A–D), type-1 collagen (E–H), and type-2 collagen (I–L). Arrows indicate positively stained HBMSCs for type-1 collagen. Scale bars1/4100 mm. Nanomagnetic dElivery Gene transfection and With the sequencing of the human genome and the advent of gene therapy has come the need to develop effective delivery and transfection agents. These agents must be able to target therapeutic and reporter genes to the relevant cells and organs both in vitro for basic investigations as well as in vivo for therapeutic applications. Recent safety concerns over the use of viral vectors has begun to shift the emphasis toward the development of non-viral delivery agents, primarily cationic lipids. Our group has been working on the development of a novel magnetic nanoparticle-based gene transfection systems based on oscillating arrays of magnets. In these “magnefect” systems, DNA or siRNA is attached to magnetic nanoparticles and oscillating arrays of magnets placed underneath a cell cul- Nanomagnetic transfection of green fluorescent protein (GFP) into PC12 neuronal cells. magnefect-LT ture plate are used to stimulate particle uptake and improve gene expression. In addition, we are developing novel, highgradient magnet arrays and new motion control systems to improve efficiency. These systems also have been commercialized. Our in vivo work in this area has focused not only on the delivery of nanoparticle/drug/gene complexes but also cells. The aim of this work is to load cells with biocompatible magnetic nanoparticles and re-introduce them into the body, using magnets to target them to repair sites or tumours. We have successfully enhanced the natural tumour homing ability of human macrophages by loading them with magnetic nanoparticle/reporter gene complexes. The uptake of these “therapeutically armed” cells into the nonvascularized, hypoxic cores of solid tumours was enhanced by more than three-fold over non-magnetized cells. Once inside the tumour, the cells can deliver a payload of “suicide” genes or cytotoxic compounds, after which AC electromagnetic fields are used to heat the particles, destroying the macrophages before they build a new blood supply to the tumour core. We have also used the technology to target human mesenchymal stem cells to tissue repair sites in small animal models. magnetic nanoparticle synthesis and characterization Our group is also active in the development of techniques for the synthesis of novel magnetic nanoparticles for biomedical applications. This work focuses on producing particles with enhanced magnetic properties or surface chemistry, as well as investigating new methods for enhanced DNA loading. Techniques such as High- Resolution Transmission Electron Microscopy and Superconducting Quantum Interference Device (SQUID) magnetometry are used for characterization of the particles. Nanoscale iron compounds in neurodeGenerative Disease Over the past 15 years we have pioneered SQUID and synchrotron-based detection techniques in order to quantify, characterize and map specific iron compounds in neurodegenerative tissue. This work aims to provide a better understanding of the role of disrupted iron homeostasis in neuro-degenerative diseases and to guide the development of chelation therapies. More recently, data from these studies has been used by us and other groups in the continuing development of MRI-based diagnostic techniques, which aim to use iron compounds formed due to neurodegenera- 7 David R. Gilland Associate Professor Ph.D., 1989, University of North Carolina, Chapel Hill Medical Imaging Positron Emission Tomography (PET) Single Photon Emission Computed Tomography (SPECT) O ur lab focuses on advancements in medical imaging with emphasis on emission tomography. We have developed a new mobile PET/SPECT system for bedside imaging. The system is capable of being moved within a hospital to image patients who cannot be easily transported to a conventional imaging facility, for example, patients in an intensive care unit. This unique device, which is currently under clinical evaluation, promises to deliver PET and SPECT imaging technology to a critically-ill patient population. We are also currently developing advanced motion compensation/image reconstruction algorithms for cardiac imaging in PET, SPECT, and CT Angiography. These algorithms have the potential to improve image quality by reducing motion blur due to cardiac contraction. The algorithms also provide a means of spatially registering images across imaging modalities. We have initiated a project with the focus of developing an improved method for imaging prostate cancer (PCa). The project includes collaborators from Johns Hopkins University, who are involved in the design of radiotracers that target prostate-specfic membrane antigens (PSMA), and from Gamma Medica-Ideas, Inc., an industry partner who are world leaders in advanced SPECT imaging detector devices. We are investigating a unique detector design that can potentially deliver improved spatial resolution and detection sensitivity for a dedicated SPECT prostate cancer imager. The potential impact of this study is to improve the staging of PCa through effective imaging methods as well as to improve the detection of recurrent cancer following treatment. The higher spatial resolution and detection sensitivity of the proposed imaging device, combined with more effective imaging agents that target PSMA, have the potential to localize small lesions in the area of the prostate gland and pelvic lymph nodes and determine the extent of intra- and extra-glandular disease. 8 A B C (A) SPECT imaging of anthropomorphic phantoms, (B,C) Mobile PET/SPECT imaging system. Rigid motion estimation for cardiac CT and SPECT Schematic of a dedicated SPECT prostate imager. Aysegul GUNDUZ Assistant Professor Ph.D. , 2008, University of Florida Neural Engineering Cognitive Neuroscience Neurorehabilitation Brain-Computer Interfaces T A PM PP Stimulus Contrast Change V2 ATTENTION AND MEMORY Button Press 1 Hz Our research program studies the neural bases and interaction of attention and memory in humans. These mechanisms have evolved in tandem because the human brain is limited in its resources to process and store information. Attention and memory are thought to be interdependent as attention promotes improved storage of information, and retrieved information from past experiences can guide what should be attended in the current scenario. The contribution of this work would be significant as attention- and memory-deficit disorders are highly associated with learning disabilities in children and aging adults. Rehabilitation of chronically lost motor functions is currently a challenge in the treatment of stroke survivors. Our goal is to determine whether surface-acquired brain signals (EEG) can feasibly be trained for recovery of volitional motor control after stroke in humans. A potential novel approach for the restoration of function and improving the quality of life of these patients could be the use of brain–computer interface (BCI) systems. So far, there is no information on whether training a patient to produce more normal brain signal features will improve motor function that involves the same areas that produce those signals. These unknown factors include the extent to which patients have detectable brain signals that can support training strategies; which brain signal features are best suited for use in restoring motor functions; and what the most effective formats are for the BCIs aimed at improving motor functions (e.g., what guidance should be provided to the user to maximize training that produces beneficial changes in brain signals). The eventual value of BCI technologies for improving motor function in individuals who have strokes or other neurological disorders depends on adequate answers to these questions. Cue B M1 BRAIN-COMPUTER INTERFACES & NEUROREHABILITATION 200 Hz 100 Hz he human brain consists of numerous networks distributed over space and connected over time to orchestrate meaningful interaction with the external world. Studying precursors to behavior and aftereffects of sensory stimulation in these recruited networks enables direct interpretation and control of this interaction. Our research aims to identify neural correlates of behavior and information processing in electrocorticographic signals (ECoG) in humans, which are collected via subdural electrodes placed on the surface of the cortex. ECoG research has strong clinical ties, as the signals are recorded from patients awaiting surgery for the treatment of intractable epilepsy. This setting facilitates rare access to the human cortex and opens unparalleled avenues for human brain research. ECoG enables the investigation of cortical networks with high spatial and temporal precision. LANGUAGE AND MEMORY Language is a distinctly human trait. No other non-human communication system compares to human language in its complexity and expressive power, and no animal aptitude approaches the universal human capacity for vocabulary. Our research is aimed at identifying the functional neocortical organization of semantic processing in humans, and to localize cortical areas of semantic memory that are distinctive from articulatory and comprehensive processing. Alterations in the cortical mechanisms supporting semantic processing lie at the heart of many language-based learning disabilities. It is estimated that developmental disorders of language (which include deficits in both oral and written language) occur in up to 20% of preschool and school-age children. Thus, revealing mechanisms by which the brain encodes comprehension and semantic memory bears important implications for our understanding of these disorders, and more importantly, will guide strategies for their amelioration. PM V2 C PP PP V2 M1 M1 Cue/Stimulus -500 ms Contrast Change/ Button Press 0 500 ms r -0.5 0 50 Hz PM 250 ms 0.5 9 david hintenlang Associate Professor Ph.D. , 1985, Brown University Diplomate, American Board of Radiology Medical Physics Imaging and Dosimetry Computed Tomography Mammography Image Guidance PATIENT RISK/BENEFIT PROCEDURES T FROM RADIOLOGIC he benefits of ionizing radiation procedures for clinical applications have been long established but continue to find new applications through faster and new imaging technologies. Many procedures are incorporated into medical specialties that have not traditionally utilized radiological techniques making it of paramount importance to accurately characterize and balance patient risks and benefits and subsequently optimize new procedures. Our laboratory focuses on the development of tools and techniques that facilitate the quantitative evaluations of dose assessment and image quality. ANTHROPOMORPHIC PHANTOMS Our laboratory has a long history of designing and fabricating anthropomorphic phantoms that accurately mimic human anatomy. It is important that the materials used in these phantoms represent the radiological properties of living human tissues, and we have developed a variety of tissue simulant materials that meet this goal. These “tissue-equivalent” materials provide the basis for fabricating whole body phantoms with accurate anatomical detail. The phantoms’ anatomy are based on high resolution CT data sets and are fabricated with state-of-the-art computer controlled machining and molding processes. Based on this methodology we have developed a family of phantoms representing newborns, pediatrics at several ages, adult females, adult males, and obese adult males. Combined with our specialized plastic scintillation detector based array dosimetry system, we have developed unique abilities to quantify organ doses 10 Figure 1: Anatomical detail represented in the cross section of an anthropomorphic phantom of a newborn. and image quality for a wide variety of patients and clinical procedures. PSD DOSIMETRY SYSTEM In order to measure radiation doses in organs distributed throughout the anthropomorphic phantoms we have developed a dosimetry system to meet the specific requirements of clinical based dosimetry. We have integrated small (a few mm) plastic scintillation detectors with a coupled fiber optic array, reader and laptop PC to provide a portable dosimetry system capable of accurately and rapidly measuring organ doses. The small physical size and near tissue-equivalence of the dosimeters and fibers are incorporated into the phantoms without perturbing the radiological integrity of the phantom tissues. The system permits sampling from an array of organ locations with instantaneous and real-time monitoring capabilities. This high resolution data provides insight into the spatial and temporal dose delivery patterns associated with modern imaging and radiation therapy systems. Current research is advancing the dosimetry system development to larger arrays and application specific detectors. Figure 2: An adult male phantom torso integrated with the PSD dosimetry system undergoing a CT procedure phantom/dosimetry system, along with image quality evaluations, allows us to better characterize, understand and develop techniques that maximize patient benefits and minimize the risks from radiological procedures. Some of the specific procedures that have been, or are under investigation include, pediatric radiography and CT, mammography, multi-detector CT, and cone-beam CT image guidance in radiation therapy. We are also actively extending phantom and tissue simulants to develop useful products for a variety of other clinical training simulators and tools. CLINICAL APPLICATIONS Our laboratory leads the development of accurate organ dose assessment from clinical procedures. The integrated Figure 3: Image quality comparison from two cone beam CT image guidance systems used in radiation therapy. Huabei Jiang J. Crayton Pruitt Family Professor Ph.D., 1988, University of Electronic Science and Technology of China Ph.D., 1995, Dartmouth College Diffuse Optical Tomography Photoacoustic Imaging Fluorescence Molecular Tomography Multi-modal Imaging Diffuse Optical Tomography of Breast Cancer B reast cancer has been one of the leading causes of death for women in the United States. Yet, the best way of combating the increased incidence of breast cancer is early detection. Therefore, there is a critical need to investigate breast cancer detection methods that could serve either a complementary or competitive role with respect to conventional x-ray mammography, which has unacceptable false negative rate for patients with radiodense breast tissues. The fundamental hypothesis of our research is that spatially and spectrally resolved NIR diffuse optical tomography (DOT) approaches offer unparallel opportunity to access the molecular and cellular signatures in breast tissue through endogenous contrast mechanisms. To clinically evaluate optical tomography based on absorption chromophores and scattering parameters, three clinical prototype imagers have been constructed. We have also developed a new contrast mechanism for NIR tomography based on refractive index/phase contrast: the initial clinical results show that the addition of refractive index can significantly improve our ability for distinguishing between malignant and benign breast lesions. Further, the opportunity exists to explore the possibility of obtaining cellular density and size from scattering spectra which together with functional parameters and refractive index should form the foundation of next generation NIR tomography for more complete characterization of breast abnormalities. Photoacoustic Imaging of Epilepsy Approximately 2.5 million Americans live with epilepsy and epilepsy-related deficits today. However, 80 percent of individuals with medication resistant epilepsy might be cured through surgery if one were able to precisely localize the seizure focus. Our research aims to significantly advance the ability to localize the focus, and thereby offer curative epilepsy surgery for this devastating disease. Photoacoustic tomography (PAT) uniquely combines the high contrast advantage of optical imaging and the high resolution advantage of ultrasound imaging in a single modality. In addition to high resolution structural information, PAT is also able to provide functional information that are strongly correlated with regional or focal seizure activity, including blood volume and blood oxygenation because of the high sensitivity of optical contrast to oxyhemoglobin and deoxyhemoglobin concentrations, and thus offers the possibility to non-invasively track dynamical changes during seizure occurrence. Multi-modal Imaging of Osteoarthritis Osteoarthritis (OA) is the most common arthritic condition worldwide and is estimated to affect nearly 60 million Americans. Besides the knees and hips, there is a subset of individuals with a predilection for developing OA of the hands and a more generalized form of OA. Due to the fact that DOT can provide high-contrast joint tissue imaging with low resolution, while x-ray can offer high-resolution joint structure with low contrast in soft tissues, we present an optimized approach that combines x-ray and optical imaging for early diagnosis of osteoarthritis in the finger joints. Fluorescence Molecular Tomography of Margin Identification of Breast Cancer Breast-conserving surgery or lumpectomy is the most common surgical procedure for patients with early invasive stages of breast cancer. However, there is no accurate method to identify tumor margins pre- or intra-operatively. To develop a sensitive approach for the detection of residual tumors in breast tissues, we have developed the Cy5.5 ATF-IO tumor targeted nanoparticles, and in combination with sensitive and high resolution NIR fluorescence tomography system, should have great potential for determining tumor margins during surgery, preventing tumor reoccurrence and therefore, increasing survival of breast cancer patients. PAT is able to image epileptic events as they are happening. The arrow in this image indicates the detected seizure. 11 Benjamin G. Keselowsky Assistant Professor Ph.D., 2004, Georgia Institute of Technology Biomaterials Cell Adhesion Vaccines Type 1 Diabetes T he Biomaterial Immuno-Engineering Lab focuses on the engineering of biomaterial-cell interactions, and targeted controlled release of immune modulating factors in order to direct immune cell function. Biomaterials undergo complex interactions with cells of the immune system upon implantation. These interactions are incompletely understood and poorly controlled, complicating the ability to achieve favorable outcomes in clinical applications. Our efforts focus on both a basic understanding of interactions of immune cells with biomaterials as well as the engineering of biomaterials capable of directing immunological processes. This work has wide-ranging implications in diverse fields such as implanted devices, therapeutic vaccines and tissue engineering. We are particularly interested in the biomaterials-based modulation of the phagocytic antigen present cell types of dendritic cells and macrophages. Microparticle-based vaccines for type 1 (autoimmune) diabetes We are engineering polymeric biomaterials-based microparticles as an injectable vaccine system to retrain the immune system, correcting aberrant activation toward pancreatic self-antigens. Microparticles with encapsulated immunomodulatory factors and insulin antigen provide targeted, controlled delivery to both intracellular and cell surface receptors of dendritic cells in vivo in order to promote tolerance in diabetes. While systemic administration of immune-modulating agents can often result in harmful offtarget effects due to uncontrolled dosing of bystander tissues, encapsulation into biodegradable microparticles can reduce the total dose required and limiting off-target effects. (Middle two panels) 12 High-throughput screening of immune cell responses to immuno-modulatory microparticles We are developing high-throughput methods to screen in vitro, microparticle-based vaccines targeting dendritic cells. The goal is to identify microparticle formulations able to shift dendritic cell phenotype toward the ability to induce regulatory T-cells and tolerance. Other research topics include: • Immune cell adhesion (to extracellular matrix proteins, to nanotopographies, and response to mechanical strain) • Receptor-mediated mechanisms of macrophage phagocytosis of orthopedic implant wear debris for the mitigation of peri-implant osteolysis in joint replacement patients Funding is gratefully acknowledged from the following sources: • National Institutes of Health (R01 DK091658, R21 AI094360) • National Science Foundation (CMMI 0927918) • Juvenile Diabetes Research Foundation • Arthritis Foundation Peter S. McFetridge Assistant Professor PhD. 2002, University of Bath, United Kingdom Research Assistant Professor/Assistant Professor, 20022009, University of Oklahoma Biomaterials and Tissue Engineering Cardiovascular Tissue Engineering Temporomandibular Joint regeneration Conductive biomaterials Periodontal Soft tissue repair Nerve regeneration Biomaterials and Tissue Engineering F rom vision and hearing implants to an artificial heart and blood vessels, biomedical engineering has become a crucial component of the drive to improve the quality of life in our ageing society. Our laboratories research aims to develop medical devices that improve the life style and reduce suffering of those afflicted with organ loss or failure. Our focus is on the use of a unique biomaterial that is used as a 3D template or bioscaffold to promote tissue/organ regeneration. This approach, called ‘Tissue Engineering’, has shown significant promise as a medical therapy, but translation from the research lab to clinic has proven difficult due to extended in vitro culture times. In light of these issues our investigations aim to understand key conditions that enhance the regenerative capacity of tissue constructs. Research objectives Our main research objective is to develop viable alternatives to autologous and synthetic transplant materials that behave more appropriately when implanted resulting in improved repair or regeneration of diseased tissues. for the repair of damaged peripheral nerves and temporomandibular joint regeneration. More specific investigations include furthering our understanding of scaffold design and function, cell adhesion, conductivity modulation and effects on cell function, and the influence of gas concentrations on organ development. Research strategy Using a patented process, vascular tissues can be rapidly, and uniformly, dissected from surrounding connective tissues, which are then processed to remove immunogenic components. This process is called decellularization and aim to minimize any immune rejection once implanted. Using the autodissection process a biomaterial with uniform mechanics and a significant potential to regenerate into neo-tissue is generated. The unique structure of these materials allows a number of vascular and non-vascular projects to be investigated, the material can be used as a direct implant (acellular), or as a re-seeded ‘living’ construct. Constructs are grown under controlled chemical and mechanical conditions within specifically designed bioreactors to circulate in vivo environment to improve tissue regeneration.. Figure 2: Biomechanics. Investigations include the analysis of material biomechanical properties during remodeling processes. Shown in Figure 2, the Young’s Modulus of cell seeded vascular scaffolds after 7 and 21 days in culture. These vascular scaffolds are cultured with human smooth muscle cells and show an increase in vessel elasticity when stimulated under perfusion flow conditions. specific research Projects are under investigation include; developing coronary and peripheral bypass grafts, tissue engineered soft-tissue implants for periodontal wound repair, conductive materials Our research encompasses the three main phases of the tissue engineering approach: 1) Biomaterial/scaffold development and characterization 2) Bioreactor design (to grow the living tissue) 3) In vitro culture of the re-seeded scaffolds under replicated physiological conditions. Figure 1: Vascular Tissue Engineering. In addition to developing functional vascular implants, our investigations focus on cellular interactions with materials with the aim to modulate the in vitro cell phenotype typically associated with diseased tissues to produce functional bypass grafts. Above left, engineered small diameter vascular graft (5mm ID) derived from human umbilical vein implanted in an ovine model to assess patency as a carotid bypass. Above right, color Doppler ultrasound monitoring graft patency and diameter after implantation. Figure 3: The interactions between novel biomaterials and cell systems. Investigations include vascular endothelial cells, smooth muscle cells, gingival fibroblasts, TMJ chondrocytes, and as above (left), neuronal cells on engineered nerves. Development and analysis of typically includes the use of unique bioreactor systems to culture cells under conditions that mimic the in vivo environment (right). 13 Brandi K. Ormerod Assistant Professor Ph.D. 2003, University of British Columbia Neural Engineering Regenerative Medicine Stem Cell Engineering Age-related Cognitive Decline Neurodegenerative Disease Biomarkers STEM CELL ENGINEERING The hippocampus is an excellent model for discovering the cues the guide stem cell growth and differentiation because it permits/promotes neurogenesis and the rate of neurogenesis can be controlled through systems variables, hormones and drugs. We are currently exploring such factors. For example, we are interested in identifying and capitalizing upon unique neurogenic features of hippocampal vasculature to stimulate neuron production in other brain regions because neurogenesis occurs in tight association with hippocampal vasculature. . Stem Cell Strategies for Neurodegenerative Disease Figure 3: When plated on mature neural networks, neural progenitor cells generate mature neurons that stimulate re-emergent developmental neuronal plasticity. Stephens et al., 2012. T he progressive death of one or more cell types in the brain is called neurodegenerative disease. Parkinson’s disease and Alzheimer’s disease are examples of incurable neurodegenerative diseases that leave patients with progressively debilitating symptoms. The Ormerod Laboratory focuses its research upon understanding how transplantable or endogenous stem/progenitor cells ccould be used to repair the diseased or damaged CNS. DCX (new neurons) BrdU (new cells) DCX/BrdU (new neurons) BIOMARKERS OF COGNITIVE AGING NEUROINFLAMMATION Figure 2: Engineering niches receptive to neuron addition may be critical for the success of neuronal regeneration strategies using stem cells. Hippocampal vasculature may contain unique features that stimulate neurogenesis that could be employed to engineer niches conducive to neuronal regeneration outside of the hippocampus. Munikoti et al., 2011 MEA CULTURE PLATFORM FOR TESTING THE VIABILITY AND SAFETY OF STEM CELL STRATEGIES Figure 1: In the hippocampus of men and mice alike, new neurons are added each day throughout life to the hippocampus (a learning and memory center) and the olfactory bulbs (important for smell). Neural progenitor cells, capable of generating new neurons, reside throughout the adult brain. Discovering factors that control the behavior of these cells is the key to unlocking new brain repair strategies with endogenous and transplantable stem cells. 14 The incidence of age-related cognitive decline grows exponentially with the advancing age of our baby boomer population. In collaboration with Dr. Tom Foster, we are discovering prognostic and diagnostic biomarkers of cognitive aging using a combined proteomic and pathway analysis approach. Because we have discovered evidence that compromised neurogenesis may accompany age-related cognitive decline and that neuroinflammation ablates neurogenesis, we are interested in developing novel immunomodulatory strategies with our biomarker data that may promote healthy aging and more effective neuronal regeneration, because all CNS injury and disease is accompanied by neuroinflammation. If you could make the perfect neuron or glial cell to replace those lost in neurodegenerative disease, would you restore neural activity and therefore reverse the symptoms of the disease? In collaboration with Dr. Tom DeMarse, we are employing microelectrode array technology to develop strategies to integrate of stem cell-derived cells into naïve and damaged long-term cultures and test their safety. We have discovered that these cells stimulate plasticity in neural networks and are currently exploring ways to capitalize on this phenomenon to restore activity in neural circuitry compromised by injuries, such as stroke. Figure 4: Potential biomarkers of impaired learning, memory and neurogenesis. Carlos Rinaldi Professor Ph.D. , 2002, Massachusetts Institute of Technology Probing Biological Environments Using Magnetic Nanoparticles Nanomedicine Cancer Nanotechnology Magnetic Nanoparticles Colloidal Hydrodynamics Transport Phenomena Suspensions of Magnetic Nanoparticles M y group studies the behavior and applications of suspensions of magnetic nanoparticles in applied magnetic fields. This field has seen explosive growth due to potential in biomedical applications such as magnetic resonance and magnetic particle imaging, biosensors, targeted delivery and triggered release of drugs, magnetomechanical actuation of cell response, and the ability to deliver magnetic energy at the nanoscale in the form of heat or shear. We combine expertise in synthesis and surface modification of magnetic nanoparticles; physical, chemical, and magnetic characterization; and modeling of the coupling of magnetic, hydrodynamic, and Brownian forces and torques to answer fundamental questions regarding the behavior of magnetic nanoparticle suspensions, understand their interaction with biological entities, and develop novel biomedical applications taking advantage of their unique properties. Engineering Cell Fate Through Nanoscale Energy Delivery by Magnetic Nanoparticles Magnetic nanoparticles can be engineered to target specific cells or even cellular components. Under an applied alternating magnetic field magnetic nanoparticles can deliver energy locally, in the form of shear due to nanoparticle rotation or in the form of heat. This ability to deliver energy at the nanoscale and selectively to targeted cells or cellular components allows for novel applications where the fate of the cell can be engineered. In one potential biomedical application, magnetic nanoparticles can be made to target cancer cells and destroy these by localized hyperthermia or through disruption of cellular components. In vitro and in vivo experiments in which cancer cells are in contact with magnetic nanoparticles and subjected to high frequency alternating magnetic fields have shown that the particles may induce significant reductions in cancer cell survival. Furthermore, because traditional cancer treatments can have synergistic effects with thermal treatment, their combination with hyperthermia induced by magnetic nanoparticles is very promising. My group is interested in understanding how nanoscale energy delivery by magnetic nanoparticles kills cancer cells, with the objective of engineering novel, more effective magnetic nanoparticlebased strategies to treat cancer. In a broader biomedical context, nanoscale energy delivery, in the form of heat and/or shear, by magnetic nanoparticles can be a tool to engineer cell fate by mechanical/thermal actuation of receptor-mediated pathways and by selective denaturation/destruction of biomacromolecules and/or cellular compartments As noted, magnetic nanoparticles can be made to rotate due to the application of alternating magnetic fields. In this line of research we take advantage of the fact that such rotation is sensitive to the mechanical properties of the environment surrounding the nanoparticles and to the presence of biomacromolecules that bind to the nanoparticle surface. In turn, the rotation of collections of magnetic nanoparticles can be observed directly with specialized microscopy techniques or remotely by monitoring their magnetization. We apply our fundamental understanding of the coupling of magnetic, hydrodynamic, and Brownian forces and torques to use magnetic nanoparticles as probes in biological complex fluids. We have recently demonstrated that by monitoring the response of magnetic nanoparticles to oscillating magnetic fields information can be obtained of the mechanical (e.g. viscous) properties of the surrounding fluid. The method requires small sample volumes (<100 ul), provides information on structural features at the scale of the probe nanoparticles, and does not require optical access to the sample. We have applied this method to study temperature-induced changes in biomacromolecules and to study breakdown of the Stokes-Einstein relationship in polymer melts. Current work aims to apply this technique to study disease-induced changes in biological fluids. Representative Recent Publications Calero, et al., Soft Matter, 7(9):4497-4503, 2011. Creixell, et al., ACS Nano, 5(9), 7124-7129, 2011. Lee, et al., Journal of Nanoscience and Nanotechnology, 11:4153-4157, 2011. Rodriguez-Luccioni, et al., International Journal of Nanomedicine, 6:373-380, 2011. 15 CHRISTINE E. SCHMIDT J. Crayton Pruitt Family Professor & Department Chair (as of January 2013) Ph.D. , 1995 University of Illinois Spinal Cord Injury Biomimetic Conducting Polymers Natural-Based Biomaterials Cell-Materials Interactions THERAPIES FOR NERVE REGENERATION D amage to spinal cord and peripheral nerve tissue can have a devastating impact on the quality of life for individuals suffering from nerve injuries. Our research is focused on analyzing and designing biomaterials that can stimulate and interface with regenerating neurons and nerves. We take a unique approach to this problem – we are using electrically conducting polymers and naturallyderived materials (e.g., hyaluronic acid-based biomaterials and chemically processed nerve tissue) to create therapies that can electrically, chemically, biologically, and mechanically trigger neurons to re-grow damaged axons. BIOMIMETIC CONDUCTING POLYMERS We are working with electroactive polymers with inherent properties that can stimulate electrically responsive cell types such as neurons. Using these polymers, our group has created new biomimetic, electronic materials by processing electrically conducting polymer composites (e.g., polypyrrole-PLGA) into 3D fiber matrices for enhanced topographical guidance. We have incorporated biological moieties using novel peptides that directly bind to conducting polymers. Ultimately, these materials can be used to interface with neurons for electronic communication or as internal “pathways” to stimulate neurons to grow and physically guide axon extension. NATURAL-BASED MATERIALS Our research group is designing tissue scaffolds that can facilitate the growth of peripheral and spinal cord axons. In this work, we are using hyaluronan, a naturally-derived biopolymer found throughout mammalian tissues. Hyaluronan 16 is non-immunogenic (i.e., not rejected by the body’s immune system) and plays a major role in wound healing and embryo development. Our group has devised novel techniques to process hyaluronan into materials that can be used in therapeutic applications. For example, we are using gels of hyaluronan to treat spinal cord lesions in rats. The gels attenuate the inflammation characteristic of spinal cord injury and provide a scaffold for regenerating axons. We have also developed “acellular tissue grafts” created from human cadaver nerves that have been chemically processed so as not to provoke an immune response in patients. These grafts have been optimized to maintain the natural intricate architecture of the nerve pathways, and thus, they are ideal for promoting the re-growth of damaged axons across lesions. These engineered nerve grafts have been translated to clinical use and are an example of how our research is promoting the development of biomedical products that can improve human health. CELL-MATERIALS INTERACTIONS Our group is also interested in the cellular mechanisms of axon extension and neuron decision making. In particular, we have created microfabricated devices for testing how neurons respond to physical and chemical environmental cues. We found that neurons favor physical cues over chemical cues when forming axons. This information has steered our research group to focus on therapeutic devices that provide topographical features to enhance regeneration of peripheral and spinal cord nerve tissue. In a parallel approach we are using advanced laser-based processes to create complex topographical patterns of cellsignaling proteins within hyaluronan materials to provide physical and chemical guidance for re-growing axons. Ranganatha Sitaram Assistant Professor Ph.D., 2008, University of Tuebingen Neural Engineering & Neuroimaging Multimodal Brain-Computer Interfaces Functional & Structural Connectomics Brain State Decoding with Pattern Recognition Neurorehabilitation of Perception, Action & Emotion INTERDISCIPLINARY APPROACH TO NEUROSCIENCE M y research is at the intersection of neuroscience, imaging and computational intelligence. It is based on the pivotal question: can modulation of brain activity in selected regions and networks lead to specific changes in sensation, perception, cognition and action, and if so what are they and how can they be used in neuroscience research and clinical treatment of neuropsychological disorders? Conceptually, my work is based on the fundamental neuropsychological paradigms of learning, namely, operant conditioning, classical conditioning and associative learning, to induce changes in the brain and behavior; combining it with innovative developments in functional and structural brain imaging, physiological measurement technology, and computational algorithms. an independent variable and recording the brain responses as dependent variables. Novel approaches incorporate a complementary philosophy where brain activity is noninvasively manipulated as an independent variable to observe the causal effects on behavior. In achieving these aims, I have applied state-of-the-art techniques in brain signal acquisition, including, real-time versions of fMRI, fNIRS, EEG/MEG, and also stimulation techniques such as transcranial magnetic stimulation (TMS) and functional electrical stimulation (FES): combining these with advanced experimental paradigms of experimental neuroscience and neuropsychology. I’m interested in applying these methods in: 1) communication and control in paralysis, 2) clinical rehabilitation of neuropsychological disorders, such as stroke, psychopathy and schizophrenia, and 3) scientific investigations in neuroscience, of emotion, cognition, motor function, and distinction between conscious and non-conscious perception. RESEARCH & TREATMENT OF EMOTIONAL DISORDERS MULTIMODAL IMAGING & BRAIN-COMPUTER INTERFACES Brain imaging in neuroscience adopts experimental paradigms correlating a particular behavioral manipulation as Another topic of research focus is the development of Functional near infrared spectroscopy (fNIRS) as a more portable and flexible imaging approach for movement research. Recent studies in my laboratory have demonstrated that fMRI and fNIRS BCIs could be used for rapid imaging and rehabilitation of stroke patients. Figure 3. (Left) Application of FES-BCI for stroke rehabilitation. (Right) Changes in functional connectivity after neuromodulation in stroke. BRAIN CONNECTOMICS Figure 2. Brain activation in a participant during volitional control of the left anterior insula, a region involved in emotion processing Figure 1. FMRI Brain-Computer Interface for neural self-regulation. NEUROREHABILITATION OF MOVEMENT DISORDERS Traditional approaches to diagnosing and treating neuropsychological and psychiatry disorders, such as depression, schizophrenia and other psychopathologies, have largely relied on subjective reports and behavioral observations of the patients, followed by pharmocological and cognitive-behavioral therapeuric interventions, with mixed results. Recent studies, applying innovative techniques in neural self-regulation and control, in clinical populations are beginning to demonstrate that patients can be trained to modulate and correct their abnormal brain leading to symptom improvements and behavioral changes. Connectomics is an emerging and exciting application of brain imaging to increase the speed, efficiency, and resolution of maps of the multitude of neural connections in the brain. My group has been focusing on the graph theoretic representation of brain’s functional and structural connectivity, integrating it with behavioral and psychological measures to study brainbehavior relationships in the healthy brain as well as in dementia, Alzheimer’s, stroke, schizophrenia and other brain “disconnections” where abnormal development and old age affect brain connectivity and hence its function. Figure 4. Graph representation of fibre connectivity, obtained from diffuse tensor imaging (DTI), and its quantification in healthy and diseased brains. 17 Johannes (Hans) van Oostrom Associate Professor and Associate Chair Ph.D., 1993, Eindhoven University of Technology, The Netherlands Simulation of Human Physiology Instrumentation BME Education al information to be gathered from existing sensors by utilizing more advanced signal processing, to enhance measurements by combining various signal sources, and by combining sensor measurements with models of human physiology to do parameter estimations that cannot otherwise be done. In one recent project, we utilized a pressure measurement mat to measure interface pressure for patients that are bedridden. Pressure ulcers are formed by too much pressure on the same location for a prolonged period of time. The standard of practice is to regularly turn the patients. Our measurements have now shown that this has limited effect, as there continue to be areas of the skin that are never unloaded. Simulation of Human Physiology P hysiology describes the processes of the human body. From the time we have understood how the human body works, we have described the physiology with mathematical equations. This can now be done at different levels, ranging from the cellular level to the organ system level. My interest in physiology simulation is at the system/organ level. Many different models describing physiology exist, but the challenge is to combine them in a cohesive fashion, and to BME Education Duration (hrs) of time interface pressures exceeded 32 mmHg (up to 5.5 hrs for one ICU patient) have a clear, open source, open model architecture that can be utilized by others. To that goal, we have been starting meetings with other international experts in the field to define a structure with which physiological models can be described. A recent project includes a model of the coronary circulation, in which we modeled the circulation of the endo- and epi-cardium, with oxygen supply and demand, modulated by the work of the heart. A graphical representation of the model allows integration into a medical school or biomedical engineering curriculum. Instrumentation Left and right myocardium. Due to an obstruction in the coronary vessel feeding the left side, the oxygen buffer is being depleted. 18 Measurements on the human body are essential for making a diagnosis of disease. Invasive measurements allow for the greatest signal fidelity, but more and more, the associated risk has reduced the frequency of these measurements. Noninvasive measurements have increased, and due to advances in signal processing, their accuracy has improved. My research focuses on new non-invasive measurements to allow addition- Biomedical engineering education is ever evolving. While degree programs have been defined for decades, to date, it is still unclear exactly what the skills of a biomedical engineer should include. In our program, we are evolving from a classroom knowledge-based setting to a truly integrative educational program in collaboration with other colleges on our campus. This includes close interactions with the Biology department and the College of Medicine. Biomedical engineers will need to understand the clinical environment very well by understanding the language clinicians speak. In addition, they need to work collaboratively with clinicians, and be comfortable in the clinical setting. To achieve this goal, we have several opportunities for our students to be immerged into the clinical arena, and our new location as part of the Health Sciences Center will make that even easier. One of my interests is to bring more collaborative learning techniques to many of our courses. Techniques such as Process Oriented Guided Inquiry Learning (POGIL) have shown that by involving the student in teams, they will learn more, and they will get the practical skill needed to work in teams and to collaborate with others. Bruce C. Wheeler Professor and Interim Chair Ph.D., 1981, Cornell University Neural Engineering Microfabrication Signal Processing Biomedical Engineering Education and Leadership BRAIN ON A CHIP T he confluence of neural cell culture and electronic microfabfication technologies enables the development of “brain on chip” technologies, where neurons are cultured on microelectrode arrays. The Wheeler laboratory has long been a leader in the development of cellular lithographic (micropatterning), electrode array and signal processing approaches to enable this work. In collaboration with Dr. Gregory Brewer of the Southern Illinois University School of Medicine, the team has been a world leader in showing how to control the growth patterns of neurons in culture. The general goal of the work is the development of technologies that enable new investigations that assist basic neuroscience researchers in understanding how networks of neurons encode information in spatiotemporal patterns. Further use of the technology is likely in areas including detecting and drug screening for neurotoxicity, as well as for applied science studies in the areas of learning, memory, development, stroke, and epilepsy. The microtunnel technology illustrated here enables us to recreate circuits from the brain. CELLULAR LITHOGRAPHY A major enabling technology is the ability to alter the chemical composition of a cell culture surface. This is achieved through stamping bioactive molecules to at¬tract or repel cells or to provide ligands to bind to specific functional receptors on the cell surfaces. This lab was an early pioneer in the development of microstamping for neural control. The precision of the cellular growth patterns is unmatched worldwide. The lab also pioneered laser ablation techniques to accomplish the same and is able to use microfluidics for similar purposes. Illinois, starting the B.S., M.S. and Ph.D. programs, serving as interim department head from 2004 to 2008. Microfabrication and Electrode Arrays The laboratory has been a long time contributor to the development of planar electrode array recording technology, originating their successful use with brain slices. Novel devices, including perforated, flexible arrays have been developed. Current work includes enhanced recording from narrow tunnels in which isolated axons grow. An unusual feature is the very large signals acquired from axons in the tunnels, enabling us to monitor the communications between discrete islands of brain tissue in adjacent wells. Signal Processing One of the great challenges in this work is the acquisition, analysis and understanding of the flood of data. Commonly, 60 channels of signals, sampled at 25 kHz, are recorded, often in trials lasting nearly a second, with up to hundreds of trials. It is desirable to be able to record continuously for periods of days. A very fundamental signal processing problem is how to analyze the data, whose complexity grows with the combinatorics of large numbers of channels and interaction times that vary from milliseconds to seconds, with experimentally relevant changes occurring in days or weeks. Current work aims to take general signal processing techniques and to focus them narrowly on relevant biological hypotheses Brain on a Chip. The brain circuit from cortex to striatum to substantia nigra is recreated in cell culture in three wells separated by two sets of tunnels, superposed over a microelectrode array. To the right are recorded action potentials showing communication among the three region. Courtesy Dr. Kucku Varghese, Mr. Sankar Alagapan. Close up of green stained neurons extending axons into the microtunnels . Close up of electrodes in microtunnels and large amplitude signals showing propagation of action potentials. Courtesy Dr. Liangbin Pan. Biomedical Engineering Education and Leadership Dr. Wheeler is the incoming President of the IEEE Engineering in Medicine and Biology Society (EMBS), the world’s largest BME society. He has served (2007-2012) as the Editor in Chief of its flagship journal, the IEEE Transactions on Biomedical Engineering. At UF he has helped lead the effort, with Dr. van Oostrom, to establish the B.S. BME degree program. Dr. Wheeler was on the faculty of the University of Illinois from 1980 to 2008. He founded the Bioengineering Department at the University of Statistical analysis of spike patterns shows how the neural network is connected. Courtesy: Dr. Thomas DeMarse. 19 J. Crayton Pruitt Family Department of Biomedical Engineering BIOMEDICAL SCIENCES BUILDING | ROOM JG56 P.O. BOX 116131 GAINESVILLE, FL 32611-6131