7/28/13 1
Transcription
7/28/13 1
7/28/13 Un-invited Guests of the Cornea: Rare and Unusual Infections Michael D. DePaolis, OD, FAAO Rochester, NY RISK FACTORS FOR ULCERATIVE KERATITIS Exogenous Ocular Adnexal Dysfunction Joseph P. Shovlin, OD, FAAO Scranton, PA Corneal Abnormalities Systemic Disease Immunosuppressive Therapy Bacterial Flora of the Normal Eye Staphylococcus epidermidis 75-90%* Diphteroids (C. xerosis) 20-33% Staphylococcus Aureus 20-25%* Streptococcus (S. viridan) Hemophilus influenza 2-6% 3% or more Streptococcus pneumoniae 1-3%* Gram negative rods 1% or more* Pseudomonas aeruginosa 0-5%* * Dominant organisms in microbial keratitis Common Organisms Encountered Common Organisms Encountered Northeast: Staph. species, Moraxella, Pseudomonas aeruginosa, Streptococcus pneumonia Southeast: Pseudomonas aeruginosa common Pseudomonas aeruginosa still a common organism in contact lens wear. Also commonly found in burn patients, patients with exposure keratopathy and those on ventaltory assistance Classification of INFILTRATES Corneal injury including foreign body: Serratia, Proteus, Azotobacter, Neisseria, Bacillus species Concern for organisms that can penetrate an intact epithelium: N. gonorrhoeae, Corynebacterium diphtheriae, Listeria, Hemophilus aegyptius 1 7/28/13 CORNEAL INFILTRATE STUDIES Factor Associated Improper lens care Bates 1989; Mah-Sadorra 2005; Matthews 1992; McNally, Chalmers ARVO 2004; Mely 2001 Lens Bioburden Corrigan 2001; Holden 1996; Key 2000; Kiernan 2009; Ozkan 2010; Sankaridurg 2000; Sweeney ARVO 2003; Szczotka-Flynn IOVS 2010 Not Associated Case contamination Bates 1989; Holden 1996; Kiernan 2009 Overnight/EW Bates 1989; Chalmers 2010; Cutter 1996; Donshik 1995; Efron 2005; Grant 1998; Mah-Sadorra 2005; Morgan BJO 2005, IOVS 2005; Nilsson 1994; Santodomingo-Rubido 2007; Stapleton 1992; Suchecki 1996; Vikoren 1990 Smoking Chalmers 2007 (trend); Cutter 1996; Morgan IOVS 2005; McNally 2003; Szczotka-Flynn 2010 Asymptomatic corneal staining Szczotka-Flynn Arch Ophthalmol 2007 Szczotka-Flynn IOVS 2010 PATH Carnt 2007 Willcox FDA 2008 Gender Morgan IOVS 2005 Chalmers 2007, OVS 2010; Forister 2009; McNally 2003; Nilsson 1994; Sweeney ARVO 2003; Szczotka-Flynn IOVS 2010 Rx Chalmers 2007 Age Chalmers 2007, ARVO 2010; McNally 2003; McNally, Chalmers ARVO 2004 Morgan IOVS 2005; Sankaridurg 1999; Sweeney 2003; Szczotka-Flynn IOVS 2010 Lens care solution Carnt 2007, 2009; Chalmers ARVO 2010; Diec ARVO 2009, ARVO 2010; Kiernan 2009; Kislan ARVO 2010; Mely CLAO 2001; Willcox FDA 2008 Donshik 1995; Morgan IOVS 2005; Roseman 1994; Zigler 2007 Soft contact lens material Brennan 2002; Carnt 2009; Chalmers 2010; Fonn 2002; Forister 2009 (trend); Keir 2010; Morgan BJO 2005, IOVS 2005; Santodomingo-Rubido 2007; Sweeney 2003; Szczotka-Flynn 2007; US FDA, Bausch & Lomb 2001 (US); US FDA, CIBA Vision,2001; US FDA, Vistakon 2005 Dillehay 2007; Efron 2005; Fonn 2002, US FDA, CIBA Vision 2001 (US) Solution/Lens combinations Carnt 2007, 2009; Keir 2010; Kislan ARVO 2010 Diec ARVO 2009; Zigler 2007 Mucin balls Carnt ARVO 2007; Sweeney ARVO 2003; Szczotka-Flynn ARVO 2010 (protective) Dumbleton AAO 1999; Tan AAO 1999 Season Chalmers OVS 2010; Morgan IOVS 2005 Tight fit/reduced movement Sweeney ARVO 2003; Ozkan 2010 Duration of lens wear Chalmers 2007 Nilsson 2001 Swimming Chalmers AAO 2004; McNally, Chalmers ARVO 2004 Morgan IOVS 2005 Prior inflammatory event, CLrelated issues, or injury Chalmers 2007; Ionides 1997; McNally 2003 Morgan IOVS 2005 Conjunctival or limbal redness Szczotka-Flynn Arch Ophthalmol 2007 Carnt 2007; Sweeney ARVO 2003 Known Association with CIEs Suchecki 1996 No Association with CIEs McNally 2003; Chalmers OVS 2010; Sankaridurg 1999 No Conclusive Consensus Characterization Of Bacteria From Contact Lens Storage Cases Of Corneal Infiltrative Event Patients Simon Kilvington1, Joseph P. Shovlin2, Marina Nikolic1. 1Corneal R&D Microbiology, Abbott Medical Optics, Santa Ana, CA; 2Northeastern Eye Institute, Scranton, PA. Of the 18 CLSC studied: The efficacy of the MPDS solutions against bacteria isolated from the storage cases after 6 hour (hr) and 14 day (d) exposure is shown in Table 3. 16/18 (89%) showed TVBC of ≥104 – 108 /mL. Conclusions 13/18 (72%) had TVBC of 106 – 108 /mL. 2/18 were dry but yielded TVBC of 104 – 105 /mL when sterile saline added. Contact lens storage cases from CIE patients can be grossly contaminated with Gram negative bacteria. Predominant bacteria such as Achromobacter, Stenotrophomonas and Delftia can be resistant to the MPDS used by the patient and able to proliferate to high numbers. The resulting microbial bioburden may initiate an immunological response resulting in CIE, either directly or from the presence of endotoxins (e.g. lipopolysaccharides) derived from the bacterial outer cell membrane. The significance of MPDS usage, degree of contact lens storage case contamination and bacterial species present in the etiology of CIE warrants further investigation. Use of disinfection systems with b r o a d a n t i m i c r o b i a l e f f i c a c y, combined with good lens storage case hygiene, may help prevent CIE and also reduce the incidence of microbial keratitis.4-5 Acanthamoeba was not isolated. All bacterial isolates were Gram negative rods of which 10/18 cases (56%) contained 13 strains of Achromobacter spp., 4/18 Stenotrophomonas maltophilia (22%), 3/18 Serratia marcescens (17%), 2/18 Delftia spp. (11%), and 6/18 (33%) Elizabethkingia spp. (3), Chryseobacterium sp. (2) and Sphingobacterium sp. (1) (Table 1). Bacteria log10 reduction Achromobacte r spp. (10 strains) S. maltophilia (4 strains) Delftia spp. (2 strains) Table 1. Bacteria identified from storage cases of CIE patients Solution CLSC +ve Organism present % OPTI-FREE® RepleniSH® 10 Achromobacter spp. 56 4 Stenotrophomonas maltophilia 22 RevitaLens Ocutec™ 3 Serratia marcescens 17 Biotrue™ 6 hr 14 d 6 hr 14 d <1 <1 <1 - 2 <1 >4a 6 hr 14 d <1 - 2 <1b Table 3. Efficacy of MPDS solutions against storage case bacteria 2 – >4c ≥4 >4 >4 ≥4 ≥4 <1 – >4d ≥4 >4 >4 ≥4 ≥4 a,b 2 Delftia spp. 11 6 Elizabethkingia sp. Chryseobacterium sp. Sphingobacterium sp. 33 Regrowth by 1-2 log for 2 strains of S. maltophilia and both Delftia spp. C 90% strains ≥4 log kill. D50% strains ≥4 log kill Contact: Simon Kilvington (simon.kilvington@amo.abbott.com) 2 7/28/13 Clinical Features of Ulcerative Keratitis Symptomotology: pain, photophobia, decreased acuity, foreign body sensation Signs: significant lid edema and reactive ptosis, conjunctival and ciliary injection, discharge, papillary response, stromal infiltration, surrounding edema, epithelial defect, anterior chamber reaction, cellular debris of tear meniscus and hypopyon Differential Diagnosis of Ulcerative Lesions Herpes simplex keratitis Neurotrophic keratitis Peripheral marginal infiltrates Chemical keratopathy Keratoconjunctivitis sicca 3 7/28/13 Culture Media Blood: aerobic organisms, saprophytic fungi Chocolate: Neisseria, Moraxella, Hemophilus Sabouraud s: fungi Thioglycolate broth: aerobic and anaerobic bacteria Lowenstein–Jensen or Middlebrook 7H-9: Nocardia, Mycobacteria species When To Culture Corneal Ulcers History of organic trauma Atypical ulcer or if a rare infection is suspected Infiltrate/suppuration involves the visual axis, infiltrate at 25% depth, 50% corneal thinning or scleral extention Immunocompromised or hospitalized patient Unresponsive to seemingly appropriate treatment LABORATORY WORKUP Up to 50% of properly performed cultures will reveal no growth in the setting of an actual bacterial keratitis (false negative) Direct inoculation of solid and liquid media is best method to increase the culture yield. Kimura spatula: culture the edge and base of the ulcer, serves to debreed the lesion Gram stain: only 12-60% accurate at predicting organism Giemsa stain: provides better morphologic characteristics of organisms and helps to distinguish bacteria from fungi 4 7/28/13 Termination of Therapy RESISTANT BACTERIA Methicillin resistant Staphylococcus aureus Measures of improvement: blunting of the perimeter of stromal suppuration, reduction in density of suppuration, reduction in cellular infiltrate and surrounding edema, reduction in anterior chamber reaction, progressive reepithelialization Reducing anti-microbials and adjuvants: avoid abrupt cessation, prolonged therapy needed for Pseudomonas, Mycobacterium, Nocardia, anaerobes Newer Generation Fluoroquinolone Resistance Trends Ocular Trust data found 3rd and 4th generation fluoroquinolone effective against 30% of MRSA isolates, while Polytrim effective against 95% of the same isolates McDoanld & Blondeau Cat & Ref Surg 36(9): 2010 Enterococcus Fecalis (group D Streptococcus) Aminoglycoside resistant Pseudomonas aeruginosa Beta lactamase producing Neisseria Atypical Mycobacteria Gram positive: Vancomycin 20-30 mg/ml, .28% Lysostaphin, IV Linezolid (Zyvos) Gram negative: Amikacin 20 mg/ml Causes of Antimicrobial Resistance Inappropriate use of antibiotics Tendency to use broader spectrum antibiotics Use of antimicrobials in an agricultural setting Spread of resistant organisms by increased international travel Up to 85% MRSA strains resistant to moxifloxacin & gatifloxacin Besifloxacin showed greater efficacy against multidrug resistant S. aureus 5 7/28/13 FLUOROQUINOLONE RESISTANCE UCSF Study (1996) Hwuang et al.: topical ciprofloxacin qid. S. aureus resistance rose from 12%-50% with in-vitro testing Wills Eye Hospital Study (1996) Rodman: S. aureus resistance - Strep. resistance 1992-4% 1992-20% 1996-13% 1996-26% LV Prasad Institute (1999) Kunimoto et al: 30.7% corneal isolates not sensitive to ciprofloxacin Bascom Palmer Eye Institute (1999) Chaudry et al: P. aeruginosa resistance rose from .44% (1991-1994) to 4.1% (1995-1998) Ocular TRUST 2: Overview Methicillin resistance in staphylococci marker for multi-drug resistance Fluoroquinolones most consistently active agents across ocular pathogens Fluoroquinolone susceptibility profile Gatifloxacin = Levofloxacin = Moxifloxacin Modest diminution in S. pneumoniae susceptibility to ciprofloxacin Polymixin B and penicillin most limited activity After 3 days of Abx MRSA MRSA must be a consideration in any external ocular infection unresponsive to standard antibiotic therapy over 2 weeks Suspicion for ocular MRSA must increase with: Malignancy Debilitating systemic disease History of ocular surface disorder Resistance to fluoroquinolones is increasing, even with 4th generation Vancomycin and gentamicin remain effective treatments Community-associated MRSA is an evolving ocular pathogen most often found in hospitalnaive patients CA-MRSA MRSE S. epidermidis and MRSE are ubiquitous commensal organisms in the human body. Among ophthalmic S. epidermidis isolates, MRSE rates may exceed 50%; MRSA rates approximately 30%. Resistance to fluoroquinolones is common among MRSE isolates. Biofilm formation fortifies S. epidemidis against antimicrobial therapies and immune defenses. Biofilms enable adhesion of bacteria to artificial surfaces such as IOLs and contact lenses. Most common cause of bacterial endophthalmitis. Additional therapies include quorem sensing and immunotherapy against biofilm antigens and anti-biofilm activity. 6 7/28/13 New Antimicrobials Collagen Cross-linking 3rd and 4th Generation Fluoroquinolones and ITQs: Trovofloxacin (Pfizer), Moxifloxacin (Bayer, Alcon), Gatifloxacin (Bristol-Myers/ Squibb, Allergan), Temafloxacin (Allergan), Gemifloxacin (Pharmacia) Peptide Antimicrobials and Inhibitors: deformylase, quorum sensing and efflux pump inhibitors Exazolidinones Pleuromutulins Oxazalidone linezolid Bacteriophages- new classes of viruses Aganocides Guidelines: The Use of Topical Steroids in Bacterial Keratitis Steroids for Corneal Ulcers Trial (SCUT) Risks vs. Benefit: - the rationale for and the case against using topical steroids Topical steroids offer no significant benefit (or risk) in treating bacterial keratitis. For: Steroids do not interfere with the ability of a bactericidal antibiotic (in sufficient concentration) to kill susceptible organisms. Adjunctive steroid therapy may improve visual outcome in severe bacterial ulcers. Against: Difficult to quantify scarring, therefore it s never been proven that steroids minimize scarring. If you kill the organisms, patients are cured . The anti-inflammatory effects of an effective antibiotic are frequently sufficient in treating bacterial ulcers. (Baum) Guidelines: The Use of Topical Steroids in Ulcerative Keratitis Principles for successful use of corticosteroids: (1) scrapings for stain and culture, (2) use of adequately dosed bactericidal antibiotics, (3) delay initiation of steroids until a clearly beneficial effect to antibiotic has been determined, (4) continue concurrent use of antibiotic with steroids, and (5) delay use of steroids if causative organism is not identified. USE 2-5 days after appropriate antibiotic therapy. Avoid if fungal infection or atypical mycobacterium is suspected, if there is severe thinning, enlarging epithelial defect, poor wound healing (diabetes), or immunosuppression. Steroids should not be used in Nocardia infections. MIC correlates with clinical results; antibiotics with lower MIC are associated with better outcomes. Srinivarsan M, Mascarenhas J, Rajaraman R et al: Corticosteroids for bacterial keratitis: The Steroids for Corneal Ulcers Trial (SCUT). Arch Ophthalmol (2012); 130(2):143-150. Non-Bacterial Corneal Ulcers Bascom Palmer Series (Alphonso et al.): 1986: 3.1% of corneal ulcers treated were not bacterial 2004-05: 64.7% of corneal ulcers treated were not bacterial ** some of the increase shift is due to 4th generation fluoroquinolone usage In Acanthamoeba keratitis, steroids may increase potential for pathogenicity and steroids likely cause an increase in the rate of excystment and suppress macrophages. 7 7/28/13 FUNGAL INFECTION IN CONTACT LENS WEAR CLINICAL FEATURES OF FUNGAL KERATITIS CLASSIFICATION/MOST COMMON ORGANISMS MOLDS - epithelium can be intact or ulcerated, usually nonsuppurative with feathery infiltrates (focal or multi-focal / satellite) Filamentous Fungi; Molds Septated: pigmented, non-pigmented Non -Septated Yeasts YEASTS - epithelium is usually ulcerated, generally suppurative (focal or diffuse) Specific: infiltrates with gray/brown pigmentation, elevated edges with rough texture 8 7/28/13 DIAGNOSIS OF KERATOMYCOSES Clinical Suspicion Corneal Scrapings Smears: gram, giemsa, acridine orange, calcofluor white Cultures: blood agar, Sabouraud s media Polymerase chain reaction Superficial Keratectomy/Biopsy Paracentesis Confocal Microscopy Confocal Microscopy: Fungal Keratitis 9 7/28/13 ANTIFUNGAL DRUGS AND THEIR MECHANISM OF ACTION Sterol Binding INITIAL THERAPY FOR FUNGAL INFECTIONS HYPHAE -Natamycin 5 % suspension, topical and oral Voriconazole, oral Ketoconazole,* Fluconazole or Itraconazole Inhibition of Sterol Synthesis Interference of RNA Synthesis Inhibition of Mitosis YEAST OR PSEUDOHYPHAE - Amphotericin B, Miconazole, Clotrimazole, Posaconazole or Flucytosine Cationic Antiseptic * Sub-conjunctival injection - Fluconazole Medical Management of Fusarium Keratitis Topical: Natamycin 5%, Voriconazole 10mg/ml, Chlorhexidine 0.2% Oral and IV: Voriconazole (Vfend/Pfizer) 200mg BID Surgical: debridement, full thickness grafting *if unresponsive, systemic posaconazole or liposomal or lyophilized Amphotericin B ** Natamycin may respond better than Voriconazole in monotherapy especially in filamentous infections. (Mycotic Treatment Trial, JAMA Ophthalmol. 131/4:422-29) Surgical Therapy Biopsy Keratectomy Penetrating keratoplasty Conjunctival flaps Cryotherapy Excimer ablation Unusual Outbreaks of Fusarium Keratitis Background: Fusarium keratitis is a relatively rare infection around the world (except in humid climates) and especially in contact lens wearers (about 5%-Bascom Plamer) Disproportionate number of ReNu with Moisture Loc users (Singapore, Hong Kong) Alphonso series: 2005-about 50% CL wear and 2006-over 70% CL wear Script trac experienced a 150% increase in Natamycin prescriptions written in 2005. 10 7/28/13 CDC Case Control Study Results Medical Management of Fusarium Keratitis Adjusted odds ratio: ReNu with MoistureLoc™-19 (2.4-944.9) p<.001 ReNu®MultiPlus™-3.6 (0.3-189) p=0.5 Topical: Natamycin 5%, Voriconazole 10mg/ml, Chlorhexidine 0.2% Conclusion: ReNu®MultiPlus™ was not significantly associated with the recent outbreak of Fusarium keratitis; Cause of strong association with ReNu with MoistureLoc™ is unclear . On-going studies looking at environmental and formulation under stress risks are continuing. Oral and IV: Voriconazole (Vfend/Pfizer) 200mg BID Surgical: debridement, full thickness grafting *if unresponsive, systemic posaconazole or liposomal or lyophilized Amphotericin B Paecilomyces lilacinus Uptick in recently reported cases in Florida in contact lens wearers Responds to Natamycin and Voriconazole Important to realize that unusual infections do occur in non-lens wearers. PROTOZOAN INFECTION IN CONTACT LENS WEAR Acanthamoeba polyphaga ACANTHAMOEBA-at least 7 species show ocular parasitology, 23 species show systemic parasitology [A.castellani, A.guina, A.culbertsoni, A.lugdunesis, A.polyphaga, A.hatchetti, A.rysades, A.griffini] Genotype (15)- 97% of isolates are of the T4 genotype Forms- 2 different life cycles 11 7/28/13 Acanthamoeba Morphology Acanthamoeba trophozoite Acanthamoeba cyst Image from: Hughes R, Kilvington S: Comparison of Hydrogen Peroxide Contact Lens Disinfection Systems and Solutions against Acanthamoeba polyphaga. Antimicrobial Agents and Chemotherapy: 2038-2043, 2001. † Tests follow FDA/ISO stand-alone criteria but are not FDA-required. Acanthamoeba Keratitis can be an Outbreak disease: History in the USA Time period Total cases 1974-1983 Cases average Comments Per year 31 3 (new infection hard to diagnose) 1984-1991 Outbreak 1150 estimate 1994-2003 (June 03) 190 estimate June 2004June 2007 485 Data from CDC Outbreak 115 (6 x normal rate) (1990=200 cases) 50% wore contact lenses but no correlation made; this is the beginning normal disease rate 85% soft contact lens wearers, nearly all used non-Sterile solutions to soak lenses due to FDA approved salt tablets 19 excludes 137 cases in the Iowa flooding outbreak 93- 96; this is the normal disease rate 121 Outbreak cause? EPA decrease of water disinfection level and a constant small number of patients using water in their lens care regimen? (2008 continues at 85 cases/yr or 4.5x the normal rate) Chicago-Gary-Kenosha 2000 Metropolitan Statistical Area Annualized Incidence Rate of Acanthamoeba Keratitis Kenosha McHenry Lake Incident AK Cases: 6/03 – 6/05 One case/ 30,000-million contact lens wearers/ year DeKalb DuPage England incidence study: 17.53-21.42/mil. Chicago data-19/mil. (Joslin); 1/8-10,000 CMP users (Schein) Proctor increase: 1.8/yr (2000-2005) to 5/yr. (2005-2006) nactual = 33 Nexpected* = 3.7 – 4.4 Kendall Will *Schaumberg DA et al, Cornea 1998 Higher prevalence in Scotland and S. Korea Seals D: Incidence of acanthamoeba keratitis in contact lens wearers. Eye, 2003; 17:893 Cook Kane Mathers data following Iowa floods (1/10,000) 0 10 ‐ 20 Porter Lake Grundy Kankakee 40 Miles 12 7/28/13 Insurgence of Acanthamoeba Keratitis Insurgence of Acanthamoeba Keratitis in Contact Lens Wear 40 confirmed cases from 6/03-11/05 in the Chicago area.* Clinical and demographic factors: chlorine levels in municipal water supplies, change in pathogenicity, environmental shifts in biofilms, attachment to new materials Background: Acanthamoeba keratitis remains a relatively rare infection among contact lens wearers with recent reports of outbreaks in some geographic areas. 88% hydrogel wearers, 12% RGP wearers Orthokeratolgy incidence: 30% of cases of microbial keratitis Kids may lack antibodies needed to ward off the infection *Joslin CE, Tu EY, McMahon TT et al: Epidemiologic characteristics of a Chicago-area acanthamoeba keratitis outbreak. Am J Ophthalmol, 142(2), 2006. AMO Recall of Complete Moisture®Plus™ Solutions Complete®Moisture Plus™ contains propylene glycol, taurine and new surfactant and lower concentration of EDTA Acanthamoeba Keratitis Case Control Studies: Relative Risk June 25, 2007 CDC interview of 79 soft lens wearers with AK: 45 (60%) reported at least some use of Complete® MoisturePlus™ in the month prior to symptom onset. Patients who used Complete® MoisturePlus™ had a relative risk of 16X or greater for contracting acanthamoeba keratitis Complete®Moisture Plus™ contained propylene glycol, taurine and surfactants with a lower EDTA concentration. Parallels with Fusarium Keratitis 2006 Outbreak Concurrent outbreaks of keratitis among CLU Multi-purpose solution implicated Fusarium: Bausch & Lomb ReNu with MoistureLoc No contamination Insufficient anti-microbial efficacy Topping off solution in case common risk factor Reduce anti-microbial efficacy CDC reports a disproportionate number of Complete® MoisturePlus™ users in data set. Complete® MoisturePlus™- 16.9, "top off" solution 2.8, <5 years wear 2.8 CDC: Verani JR, Lorick SA, Yoder JS, et al. National outbreak of Acanthamoeba keratitis associated with the use of a contact lens solution. Emerg. Infect. Dis. 2009;15(8):1236-1242. Complete® MoisturePlus™- 18.51, Re-use of solution (.5/mo.)- 3.17, "rub" (<10/mo.)9.05, showering with lenses (>5/mo.)- 9.07, case replacement (>3 mos.)- 2.79 Joslin: Joslin CE, Tu E, Shoff ME, et al. The association of contact lens solution use and Acanthamoeba keratitis. Am J Ophthalmol 2007;29(5):1-8. Epidemic Intelligence Conference CDC, April, 2012 Elevated Acanthamoeba Keratitis Incidence Despite a 2007 Outbreak-Associated Product Recall-A Multi-State Investigation, 2008-2011 Brown AC, Ross J, Yoder J, Ayers T, Roy S and Beach M. Multiple CL hygiene practices were associated with increased risk of AK. The observed persistence of AK might be due to enhanced disease awareness and clinical suspicion following the 2007 investigation. To prevent infection, CL wearers should observe recommended CL care practices. RISK FACTORS: topping off solutions 4.54X, recently starting CL use 3.22X, storing CL in water 5.37X, and handling CLs with wet hands 2.17X Concern about safety of multi-purpose solutions 13 7/28/13 MANNOSE-BINDING PROTEIN (MBP) IS A CRUCIAL LIGAND FOR ADHESION TO THE CORNEAL EPITHELIUM Acanthamoeba Proxy Legionellosis- live inside amoeba Increased reporting in Japan (2004) Causes Legionnaires disease (gram negatve bacteria) Neil K. Acanthamoeba and its association with Legionellosis. Clin Infect Dis, 14(9), 2000 Wheat and Rice Food Source Stenotrophomonas maltophilia and Delftia acidovorans are bacteria commonly found in cases where there is contamination with Acanthamoeba. SYMPTOMATOLOGY IN ACANTHAMOEBA KERATITIS Symptoms: Usually unilateral pain disparate to findings, history to trauma and/or contact lens wear, symptoms wax and wane with chronicity Strategies in designing new MPS: minimizing encystment (1.5X evaporation from topping off doubled encystment rate with Complete®MoisturePlus) Nikolic M, Kilvington S, Cheung S, et al. Survival and growth of Stenotrophomonas maltophilia, ARVO abstract #1540-D831, May 2010, Fort Lauderdale. CLINICAL FEATURES OF ACANTHAMOEBA KERATITIS EPITHELIAL: patchy epithelial involvement (stellate, irregular or pleomorphic epitheliopathy) bull s eye lesion, white spots, persistent epithelial defect, elevated corneal lines STROMAL: lack of vascularization, granulomatous or nonsuppurative inflammation, radial nerve infiltrates ( lightning flash ), ring infiltrate OTHERS: pseudoguttata, hyphema, hypopyon, pseudomembrane, scleritis, episcleritis, adenopathy, decreased corneal sensation (initial) **poor response to therapy may suggest co-infection 14 7/28/13 DIAGNOSTIC CONFUSION WITH DENDRIFORM LESIONS OF THE CORNEA Acanthamoeba elevated corneal line Herpes simplex dentrite Herpes zoster keratopathy Contact lens pseudo-dendrite Thygeson s superficial keratopathy Tryosinemia (Richner-Hanhart) Other corneal fascinations-edematous formations, verticillata, filaments, stromal dystrophy, post PK hypertrophic epitheliopathy 15 7/28/13 DIAGNOSIS OF ACANTHAMOEBA KERATITIS Clinical Suspicion Corneal Scrapings Superficial Keratectomy / Biopsy Paracentesis Confocal Microscopy Soft Lens Inspection 16 7/28/13 Higher resolu7on OCT can visualize pathogens Confocal Microscopy: Acanthamoeba Keratitis Acanthamoeba in 0.25% agar THERAPY FOR ACANTHAMOEBA KERATITIS ANTIBIOTICS / Aminoglycosides** ANTI FUNGALS (anti-trophozoite agents) ANTIPARASITICS / Aromatic Diamidines Clinical Outcome In Treating Acanthamoeba Keratitis Propamidine and neomycin: 9/19 (47%) Meisler Propamidine and PHMB: 8/10 (80%) McCulley 105/111 (96%) Wilhelmus Propamidine and chlorhexidine: 40/42 (96%) Seals BIOCIDES / CATIONIC ANTISEPTICS Intensive monotherapy with either PHMB or chlorhexidine may be equally as effective. Note: No one case acts in the same manner ** Role of corticosteroid treatment is controversial **aminoglycosides have now shown increased neomycin resistant strains with an increased preponderance for trophozoite transformation 17 7/28/13 PREVENTION OF ACANTHAMOEBA KERATITIS IN CONTACT LENS WEAR Avoid use of saliva, distilled and tap/well water Avoid swimming and hot tubs while wearing contact lenses Precautions while showering with lenses in place Hygiene related variables: proper maintenance and care of lenses includes a rub and rinse , not topping off , and replacing lenses and cases regularly. ADDITIONAL PROTOZOAN Naegleria Hartmanella Vahlkampfiid Microsporidia Rhinosporidia Oxidative disinfection has reasonably good cysticidal effects. MICROSPORIDIA KERATITIS Presents as a superficial punctate, multifocal keratitis and a stromal keratitis is possible following trauma Nasopharyngeal or urinary colonization in HIV infected patients Improvement with albendazole and topical fumagillin bicyclohexyl ammonium salts Repeated debridement (perhaps even swabbing) seems to be therapeutic especially in immunocompetent patients. *may be best classified as a fungus 18 7/28/13 19 Un-invited Guests of the Cornea: Rare and Unusual Infections Michael DePaolis, OD, FAAO Joseph P. Shovlin, OD, FAAO Several rare corneal pathogens causing infections in contact lens wearers have been identified. What make these infections so difficult to manage are often the late definitive diagnosis and the paucity of effective anti-microbial agents that impact a clinical cure. A timely diagnosis including appropriate differentials in contact lens wearers with ulcerative keratitis will be stressed along with a review of recent protocols for managing rare bacterial, fungal and protozoan infections of the eye. RISK FACTORS AND THE PATHOGENESIS OF ULCERATIVE KERATITIS RISK FACTORS FOR BACTERIAL CORNEAL ULCERS EXOGENOUS: contact lenses, especially extended wear, contaminated cases and solutions, patching a contact lens abrasion; trauma including foreign body, chemical and thermal injury; previous ocular surgery including loose sutures; medicamentosa, contaminated medications and make-up. OCULAR ADNEXAL DYSFUNCTION: misdirection of lashes; abnormal lid anatomy & function; tear deficiencies, conjunctivitis; neuropathy involving cranial nerve(s) III, V and VII; blepharitis, canaliculitis/dacryocystitis. CORNEAL ABNORMALITIES: hypesthesia, bullous keratopathy, erosive disorders, viral keratitis. SYSTEMIC DISEASE: diabetes mellitus; debilitating illness, especially malnutrition or respirator dependence; collagen vascular disorders, substance abuse, mental illness; exfoliative skin disease; immunocompromised patient; atopic dermatitis, vitamin A or B deficiency. IMMUNOSUPPRESSIVE THERAPY: systemic corticosteroids; topical immunosuppressive agents; systemic chemotherapy for malignancy, organ transplant or collagen vascular disease. FUNGAL AND PROTOZOAN INFECTIONS FUNGAL KERATITIS Fungi are primitive non-motile plant-like organisms. Yeast are uni-cellular and molds are multi-cellular filamentous structures. In the past 10 years there has been a definite increase in the prevalence of fungal keratitis in certain geographic areas, although nationwide there are probably only 300 cases per year. There are 40 different genera that cause keratomycoses; most are saprophytic. CLASSIFICATION/MOST COMMON ORGANISMS (Adapted from J. McCulley) Filamentous fungi; Molds Septate- most common cause of fungal keratitis, variable geographic distribution, mostly in the southern and southwestern United States,- Fusarium (most virulent due to complex enzymes + toxins), Aspergillus, Curvularia, Paecilomyces, Phialophora Non-septate- Mucoraceae (rare corneal pathogen) Risk Factors: corneal injury (frequently a tree branch or vegetative matter in an agricultural setting), soft contact lens wear (extended wear/therapeutic), chronic topical medication, systemic steroids, diabetes mellitus, radial keratotomy. CLINICAL FEATURES Epithelium Type of stromal inflammation Site of inflammation* Typical Atypical, severe intact or ulcerated non-suppurative, feathery infiltrate(s) focal or multi-focal, satellite infiltrates ulcerated suppurative diffuse *typically accompanied by a mild iritis, endothelial plaque and hypopyon in severe infections; hypopyon is of no diagnostic value Yeasts- worldwide distribution: Candida- C. albicans, C. parapsilosis, C. tropicalis Risk Factors- protracted ulceration of the epithelium, topical steroid therapy, penetrating keratoplasty, bandage soft lenses Epithelium Type of stromal inflammation Site of inflammation Typical, common Atypical, rare ulcerated suppurative intact non-suppurative focal or diffuse multifocal Note: ring infiltrates or abscess is possible with an intact epithelium KERATOMYCOSES DIAGNOSIS- clinical suspicion, corneal scraping, superficial keratectomy (paracentesis) Diagnostic stains- gram, Giemsa, GMS, PAS, KOH, acridine orange, Schwartzman’s, calcofluor white Culture media- Sabouraud dextrose agar (with gentamicin, without Confocal cyclohexamide), blood agar, brain-heart infusion agar with gentamicin @ 25 + 37 C microscopy- identifies hyphae, poor for Candida, a guide to therapeutic response ANTIFUNGAL DRUG MECHANISMS OF ACTION1. Sterol Binding- Polyene drugs like Amphotericin B, Nystatin and Natamycin 2. Inhibition of Sterol Synthesis- the Imidazoles including Miconazole, Ketoconazole, Clotrimazole, Fluconazole 3. Interference with RNA Synthesis- Flucytosine (fluorinated pyrimidine) and Itraconazole (antimetabolites) 4. Inhibition of Mitosis- Griseofulvin 5. Cationic Antiseptic- chlorhexidine INITIAL THERAPY- drugs are generally not introduced until definitive diagnosis is made. Topical*-HYPHAE-Natamycin 5% (Natacyn) suspension (every hr. for 2448 hrs.) YEAST OR PSEUDOHYPHAE- Amphotericin B .1-.5% (Fungizone) (every 15-20 minutes for 24-48 hrs.), Miconazole 1% (Micatin, Monistat) (every hr., but very toxic) as an alternate therapy. Clotrimazole (cream or powder) and Flucytosine (Ancobon tablets) converted to a 1% solution have been effective against Candida infection. Oral- Ketoconazole (Nizoral) (200-400 mg/day) or Fluconazole (Diflucan) (100-200 mg/day) [generally used for hyphae and endophthalmitis; Candida generally responds to topicals alone]; Itraconazole (Sporanox) is more effective against filamentous fungi especially Aspergilli .Reserve systemic treatment for deep keratitis, impending perforation, scleritis, endophthalmitis and post penetrating keratoplasty. Sub-conjunctival injection-Fluconazole (Diflucan) .5ml = 1mg daily pending initial response and identification of the organism. Other agents- atropine 1% or hyoscine .25% 4x/day; glaucoma medication as needed; role of collagen shield as a delivery device not well defined. Avoid steroids in fungal keratitis since mold/yeast replicate more freely and microbial agents are generally only fungistatic. *topicals are often continued for 6 wks. or longer; watch for toxicity Note: excimer ablation may be of some value unless there is deep penetration. PREVENTION-minimize extended wear, therapeutic lens application whenever possible, avoid indiscriminate use of topical steroids. ACANTHAMOEBA KERATITIS Acanthamoeba keratitis remained a curiosity in the past; however recently this pathogen affecting primarily the cornea and sclera is recognized with increased frequency. Early detection will alter the course of therapy and ultimately affect outcome, therefore early diagnosis is critical. The risks factors that have been identified by epidemiologic studies, specifically as they relate to contact lens wear will be examined. THE ORGANISM- "a free living" protozoan (motile) with worldwide distribution; isolated from fresh water, well water, sea and brackish water, sewage, hot tubs, air, soil, wheat and barley; there may be high incidence areas following disasters (ie. Sacramento floods and hurricane, "Hugo") Acanthamoeba: >7 species show ocular parasitology [A. castellani, A. quina, A. culbertsoni, A. lugdunesis, A. polyphaga, A. hatchetti, A. rysodes, A griffini] Note: Sequence types are recommended as much less ambiguous units of classification than currently used species names. Forms: cyst (sessile)*and trophozoite (motile) *makes the organism resistant to freezing, desiccation, standard chlorination and a variety of antimicrobial agents OCULAR INFECTION Clinical features-initial signs are non-specific; they include: patchy epithelial involvement (irregularity or pleomorphic focal or stellate epitheliopathy), suppurative/granulomatous or non-suppurative stromal keratitis, “bull’s eye” lesions, pseudo-guttata and iritis. More advanced signs include: a radial kerato-neuritis ("lightning flash"), ring infiltrate, nodular episcleritis, scleritis and hypopyon or hyphema; there may be a pseudo-membrane or adenopathy present. A remarkable lack of vascularization; is often the only feature to help differentiating this infection from herpes simplex. Recently, early signs identified include a bull’s-eye lesion and the appearance of randomly distributed white spots on the cornea. Persistent epithelial defects immediately following penetrating keratoplasty may signal early amoebic infection. Symptomatology-usually unilateral pain disparate to ocular findings, often history to trauma +/or contact lens wear, symptoms generally wax and wane over time with chronicity. LABORATORY CONFIRMATION Corneal scrapings*- examined with Giemsa or tri-chrome stains, also culture with heated killed E. coli on non-nutrient agar or activated charcoal/yeast extract; other valuable tests include immunofluorescent techniques which include: calcofluor white and indirect immunofluorescent antibody testing. Standard culture negativity for bacteria, fungi, and virus expected. Cysts can sometimes be seen on soft lenses with high magnification. Confocal microscopy is an aid to early differential diagnosis, and the infection produces a "lightning flash" appearance at the radial nerve infiltrates. Polymerase chain reaction may be more sensitive than cultures as a diagnostic test. PCR analysis of the tears and epithelium may prove a useful tool in confirming an early diagnosis. *biopsy with intact epithelium or graft histology THERAPY Reported improvement*Antibiotic/Aminoglycoside: paromomycin (Humatin), neomycin Antifungal: clotrimazole, ketoconazole (Nizoral), itraconazole (Sporanox), miconazole (Monistat, Micatin), fluconazole (Diflucon) Antiparasitic/Aromatic Diamidine: propamidine isethionate (Brolene), hydroxystilbamidine (Pentamidine),hexamidine di-isethionate (Desomedine) Biocide/Cationic Antiseptic: polyhexamethylene biquanide (PHMB, Baquacil, Cosmocil), chlorhexidine digluconate, povidone-iodine (Betadine) *use one agent from the biocide/cationic antiseptic group plus one or more from the above list, for recalcitrants with significant ocular toxicity use drops in a three day cycle (hexamidine, paromomycin, and either PHMB or chlorhexidine Supportive and adjunct therapy-debridement, conjunctival flaps, bandage lenses, debulking procedures, cryotherapy and steroids with caution**; grafts show a high recrudescence (NSAIDs seem to have little benefit in pain reduction when radial keratoneuritis is present) **inhibits metamorphogenesis and increases pathogenicity by accelerating trophozoite proliferation Success has been reported by Seals (1995) using .02% chlorhexidine digluconate & .1% propamidine isethionate has been reported. CONTACT LENS RELATED RISK FACTORS/ PREVENTION Accouterment- use of distilled water, tap/well water*, or saliva; bacterial contamination of case and care system a common factor *recent concern especially with rigid lens wear Disinfection- some resistance to chemical disinfection Corneal trauma- hypoxia, mechanical trauma with lens wear Note: should avoid swimming and using hot tubs with contact lens wear ADDITIONAL PROTOZOAN Other amoeba- A similar infection may be caused by another amoeba besides Acanthamoeba, such as Naegleria, Hartmanella or Vahlkampfiid. Microsporidia- an obligate intracellular protozoan recently found on corneal scrapings of HIV infected patients from nasopharyngeal or urinary colonization. Generally it presents as a superficial punctate, multifocal keratitis (may be confined to the superficial cornea for months) in immuno-incompetent patients (genus-Encephalitozoon); a stromal keratitis is possible following trauma especially in immunocompetent individuals (genusNosema). A slight improvement has been noted with trimethoprim/sulfisoxazole. Recently itraconazole, propamidine isethionate, albendazole (benzimidazole), and especially topical fumagillin bicyclohexylammonium salt (Fumadil B), a bacteriostatic antibiotic secreted by Aspergillus, have shown some promise. Diagnosis is made by Gram’s stain, cytology with chromotrope-based stain, or by using electron or confocal microscopy.