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1 General aspects (0)   1.1 Epidemiology (2)   1.2 Population genetics (5)   1.3 Pathogenesis (5)   1.4 Quality of life (2)   1.5 Glaucomas as cause of blindness (3)   1.6 Prevention and screening (3) 2 Anatomical structures in glaucoma (0)   2.1 Conjunctiva (2)   2.2 Cornea (6)   2.3 Sclera (1)   2.4 Anterior chamber angle (0)   2.5 Meshwork (0)     2.5.1 Trabecular meshwork (7)     2.5.2 Schlemms canal (1)     2.5.3 Scleral outlet channels (0)   2.6 Aqueous humor dynamics (1)     2.6.1 Production (1)     2.6.2 Outflow (3)       2.6.2.1 Trabecular meshwork (0)       2.6.2.2 Uveoscleral (0)     2.6.3 Compostion (9)   2.7 Episcleral veins and venous pressure (0)   2.8 Iris (1)   2.9 Ciliary body (2)   2.10 Lens (1)   2.11 Vitreous body (0)   2.12 Choroid, peripapillary choroid, peripapillary atrophy (3)   2.13 Retina and retinal nerve fibre layer (21)   2.14 Optic disc (17)   2.15 Optic nerve (3)   2.16 Chiasma and retrochiasmal central nervous system (0)   2.17 Stem cells (0)   2.20 Other (0) 3 Laboratory methods (0)   3.1 Microscopy (0)   3.2 Electron microscopy (1)   3.3 Immunohistochemistry (14)   3.4 Molecular genetics (4)     3.4.1 Linkage studies (15)     3.4.2 Gene studies (1)   3.5 Molecular biology incl. SiRNA (4)   3.6 Cellular biology (2)   3.7 Biochemistry (1)   3.8 Pharmacology (0)   3.9 Pathophysiology (2)   3.10 Immunobiology (0)   3.11 Pharmacogenetics (0)   3.12 Proteomics (0)   3.13 In vivo imaging (0)     3.13.1 Laser Scanning (0)       3.13.1.1 Confocal Scanning Laser Ophthalmoscopy (0)       3.13.1.2 Confocal Scanning Laser Polarimetry (0)     3.13.2 Optical Coherence Tomography (0)       3.13.2.1 Anterior Segment (0)       3.13.2.2 Posterior Segment (0)     3.13.3 RGC Imaging (0)     3.13.4 Other (0)   3.20 Other (1) 4 Tissue culture of ocular cells (0) 5 Experimental glaucoma; animal models (19)   5.1 Rodent (0)   5.2 Primates (0)   5.3 Other (0) 6 Clinical examination methods (2)   6.1 Intraocular pressure measurement; factors affecting IOP (22)     6.1.1 Devices, techniques (0)     6.1.2 Fluctuation, circadian rhythms (0)     6.1.3 Factors affecting IOP (0)   6.2 Tonography, aqueous flow measurement (see also 2.6) (0)   6.3 Biomicroscopy (slitlamp) (1)     6.3.1 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Refractive errors in relation to glaucoma (1)   8.1 Myopia (1)   8.2 Hypermetropia (0)   8.3 Contact lenses (0)   8.4 Refractive surgical procedures (1)   8.5 Other (0) 9 Clinical forms of glaucomas (0)   9.1 Developmental glaucomas (1)     9.1.1 Congenital glaucoma, Buphthalmos (2)     9.1.2 Juvenile glaucoma (0)     9.1.3 Syndromes of Axenfeld, Rieger, Peters, aniridia (3)     9.1.4 Other (1)   9.2 Primary open angle glaucomas (0)     9.2.1 Ocular hypertension (1)     9.2.2 Other risk factors for glaucoma (7)     9.2.3 Open angle glaucoma with elevated IOP (0)     9.2.4 Normal pressure glaucoma (6)   9.3 Primary angle closure glaucomas (5)     9.3.1 Acute primary angle closure glaucoma (pupillary block) (3)     9.3.2 Chronic primary angle closure glaucoma (pupillary block) (2)     9.3.3 Plateau iris syndrome (0)     9.3.4 Primary angle closure suspect (0)     9.3.5 Primary angle closure (0)     9.3.10 Other (3)   9.4 Glaucomas associated with other ocular and systemic disorders (0)     9.4.1 Steroid-induced glaucoma (3)     9.4.2 Glaucomas associated with disorders of the cornea, conjunctiva, sclera (0)       9.4.2.1 Iridocorneal endothelial syndrome (ICE, incl. irisatrophy) (0)       9.4.2.2 Posterior polymorphous dystrophy (0)       9.4.2.3 Fuchs' endothelial dystrophy (0)       9.4.2.5 Other (0)     9.4.3 Glaucomas associated with disorders of the iris and ciliary body (0)       9.4.3.1 Pigmentary glaucoma (0)       9.4.3.5 Other (0)     9.4.4 Glaucomas associated with disorders of the lens (1)       9.4.4.1 Exfoliation syndrome (8)       9.4.4.2 Glaucomas associated with cataracts (2)       9.4.4.3 Glaucomas associated with lens dislocation (0)       9.4.4.5 Other (0)     9.4.5 Glaucomas associated with disorders of the retina, choroid and vitreous (1)       9.4.5.1 Neovascular glaucoma (3)       9.4.5.5 Other (0)     9.4.6 Glaucomas associated with inflammation, uveitis (3)     9.4.7 Glaucomas associated with ocular trauma (0)     9.4.8 Glaucomas associated with intraocular tumors (0)     9.4.9 Glaucomas associated with elevated episcleral venous pressure (0)       9.4.10 Glaucomas associated with hemorrhage (0)     9.4.11 Glaucomas following intraocular surgery (0)       9.4.11.1 Ciliary block (malignant) glaucoma (0)       9.4.11.2 Glaucomas in aphakia and pseudophakia (1)       9.4.11.3 Epithelial, fibrous, and endothelial proliferation (0)       9.4.11.4 Glaucomas associated with corneal surgery (0)       9.4.11.5 Glaucomas associated with vitreoretinal surgery (1)     9.4.15 Glaucoma in relation to systemic disease (12)     9.4.20 Other (1) 10 Differential diagnosis e.g. anterior and posterior ischemic optic neuropathy (7) 11 Medical treatment (0)   11.1 General management, indication (10)   11.2 Cholinergic drugs (0)   11.3 Adrenergic drugs (0)     11.3.1 Epinephrine (0)     11.3.2 Thymoxamine, dapiprazole (0)     11.3.3 Apraclonidine, brimonidine (8)     11.3.4 Betablocker (14)     11.3.5 Other (0)   11.4 Prostaglandins (23)   11.5 Carbonic anhydrase inhibitors (0)     11.5.1 Systemic (0)     11.5.2 Topical (11)   11.6 Osmotic treatment (1)   11.7 Treatment of bloodflow (3)   11.8 Neuroprotection (14)   11.9 Gene therapy (0)   11.13 Combination therapy (0)     11.13.1 Betablocker and pilocarpine (0)     11.13.2 Betablocker and carbon anhydrase inhibitor (0)     11.13.3 Betablocker and brimonidine (0)     11.13.4 Betablocker and prostaglandin (0)     11.13.5 Other (0)   11.14 Investigational drugs; pharmacological experiments (7)   11.15 Other drugs in relation to glaucoma (1)   11.16 Vehicles, delivery systems, pharmacokinetics, formulation (6)   11.17 Cooperation with medical therapy e.g. persistency, compliance, adherence (0)   11.20 Other (6) 12 Surgical treatment (0)   12.1 General management, indication (7)   12.2 Laser iridotomy (0)   12.3 Laser iridoplasty (0)   12.4 Laser trabeculoplasty and other laser treatment of the angle (3)   12.7 Surgical iridectomy (0)   12.8 Filtering surgery (0)     12.8.1 Without tube implant (4)     12.8.2 With tube implant or other drainage devices (7)     12.8.3 Non-perforating (12)     12.8.4 Using laser (0)     12.8.5 Other (0)     12.8.10 Woundhealing antifibrosis (13)     12.8.11 Complications, endophthalmitis (8)   12.9 Trabeculotomy, goniotomy (0)   12.10 Cyclodestruction (5)   12.11 Cyclodialysis (3)   12.12 Cataract extraction (1)     12.12.1 Intracapsular (0)     12.12.2 Extracapsular (0)     12.12.3 Phacoemulsification (2)   12.14 Combined cataract extraction and glaucoma surgery (3)     12.14.1 Intracapsular (0)     12.14.2 Extracapsular (0)     12.14.3 Phacoemulsification (5)   12.15 Capsulotomy (0)   12.16 Vitrectomy (0)   12.17 Anesthesia (2)   12.20 Other (2) 13 Therapeutic prognosis and outcome (0)   13.1 Prognostic factors (0)   13.2 Outcome (0)     13.2.1 IOP (0)     13.2.2 Visual field (0)       13.2.2.1 Progression (0)       13.2.2.2 Improvement (0)     13.2.3 Other (0) 14 Costing studies; pharmacoeconomics (0) 15 Miscellaneous (1)

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Abstract #10475 Published in IGR 6-1

Neuroretinal function during systemic hyperoxia and hypercapnia in humans

Kergoat H; Tinjust D
Optometry and Vision Science 2004; 81: 214-220

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PURPOSE: Breathing pure oxygen (O₂) or carbogen is known to have differential effects on the retinal and choroidal blood flow. The objective was to evaluate the effects these hemodynamic changes have on various retinal neurons receiving their vital nutrients from these two vascular beds. To that effect, the authors recorded the photopic flash electroretinogram (fERG) and oscillatory potentials (OPs) in humans. METHODS: Eighteen adults participated in two test sessions to examine the effects of breathing pure O₂ or carbogen on the fERGs and OPs. The retinal potentials were recorded at the end of each of the following breathing phases: (1) room air for five minutes, (2) pure O₂ or carbogen for five minutes, (3) immediately after the flow of gas was stopped, and (4) ten minutes after the flow of gas was stopped. The heart rate, respiratory rate, oxygen saturation (Sao2), and end-tidal carbon dioxide (Etco2) were monitored. Blood pressure and intraocular pressure were measured to derive the ocular perfusion pressure. RESULTS: Breathing pure O₂ increased Sao2, decreased heart rate and Etco2, but did not alter respiratory rate and ocular perfusion pressure. Breathing carbogen increased Sao2, Etco2, and ocular perfusion pressure, decreased respiratory rate but did not alter heart rate. fERGs and OPs were not detrimentally affected by breathing either pure oxygen or carbogen. Only OP4 was delayed at the end of testing in the O₂ session. CONCLUSIONS: These results show that the neural generators of the photopic fERGs and OPs in humans are largely unaltered by the degree of systemic hyperoxia and hypercapnia induced and their reported effects on retinal and choroidal hemodynamics. These results, combined with earlier studies showing that some components of the scotopic fERGs and OPs were altered during similar testing conditions, suggest that the photopic system is more resistant than the scotopic system to altered ocular hemodynamics.

Dr. H. Kergoat, Ecole d'optometrie, Universite de Montreal, Montreal, Quebec, Canada. helene.kergoat@umontreal.ca

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Classification:

6.7 Electro-ophthalmodiagnosis (Part of: 6 Clinical examination methods)

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