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1 General aspects (0)   1.1 Epidemiology (13)   1.2 Population genetics (0)   1.3 Pathogenesis (6)   1.4 Quality of life (7)   1.5 Glaucomas as cause of blindness (5)   1.6 Prevention and screening (6) 2 Anatomical structures in glaucoma (0)   2.1 Conjunctiva (6)   2.2 Cornea (17)   2.3 Sclera (14)   2.4 Anterior chamber angle (6)   2.5 Meshwork (0)     2.5.1 Trabecular meshwork (16)     2.5.2 Schlemms canal (4)     2.5.3 Scleral outlet channels (2)   2.6 Aqueous humor dynamics (0)     2.6.1 Production (0)     2.6.2 Outflow (0)       2.6.2.1 Trabecular meshwork (1)       2.6.2.2 Uveoscleral (0)     2.6.3 Compostion (1)   2.7 Episcleral veins and venous pressure (0)   2.8 Iris (6)   2.9 Ciliary body (1)   2.10 Lens (1)   2.11 Vitreous body (0)   2.12 Choroid, peripapillary choroid, peripapillary atrophy (18)   2.13 Retina and retinal nerve fibre layer (33)   2.14 Optic disc (34)   2.15 Optic nerve (2)   2.16 Chiasma and retrochiasmal central nervous system (4)   2.17 Stem cells (5)   2.20 Other (0) 3 Laboratory methods (0)   3.1 Microscopy (5)   3.2 Electron microscopy (0)   3.3 Immunohistochemistry (4)   3.4 Molecular genetics (0)     3.4.1 Linkage studies (2)     3.4.2 Gene studies (29)   3.5 Molecular biology incl. 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Refractive errors in relation to glaucoma (0)   8.1 Myopia (10)   8.2 Hypermetropia (1)   8.3 Contact lenses (1)   8.4 Refractive surgical procedures (0)   8.5 Other (0) 9 Clinical forms of glaucomas (0)   9.1 Developmental glaucomas (0)     9.1.1 Congenital glaucoma, Buphthalmos (17)     9.1.2 Juvenile glaucoma (21)     9.1.3 Syndromes of Axenfeld, Rieger, Peters, aniridia (3)     9.1.4 Other (0)   9.2 Primary open angle glaucomas (0)     9.2.1 Ocular hypertension (11)     9.2.2 Other risk factors for glaucoma (5)     9.2.3 Open angle glaucoma with elevated IOP (1)     9.2.4 Normal pressure glaucoma (15)   9.3 Primary angle closure glaucomas (0)     9.3.1 Acute primary angle closure glaucoma (pupillary block) (9)     9.3.2 Chronic primary angle closure glaucoma (pupillary block) (7)     9.3.3 Plateau iris syndrome (2)     9.3.4 Primary angle closure suspect (0)     9.3.5 Primary angle closure (3)     9.3.10 Other (0)   9.4 Glaucomas associated with other ocular and systemic disorders (0)     9.4.1 Steroid-induced glaucoma (7)     9.4.2 Glaucomas associated with disorders of the cornea, conjunctiva, sclera (1)       9.4.2.1 Iridocorneal endothelial syndrome (ICE, incl. irisatrophy) (1)       9.4.2.2 Posterior polymorphous dystrophy (0)       9.4.2.3 Fuchs' endothelial dystrophy (0)       9.4.2.5 Other (1)     9.4.3 Glaucomas associated with disorders of the iris and ciliary body (0)       9.4.3.1 Pigmentary glaucoma (1)       9.4.3.5 Other (0)     9.4.4 Glaucomas associated with disorders of the lens (0)       9.4.4.1 Exfoliation syndrome (14)       9.4.4.2 Glaucomas associated with cataracts (0)       9.4.4.3 Glaucomas associated with lens dislocation (0)       9.4.4.5 Other (1)     9.4.5 Glaucomas associated with disorders of the retina, choroid and vitreous (0)       9.4.5.1 Neovascular glaucoma (6)       9.4.5.5 Other (9)     9.4.6 Glaucomas associated with inflammation, uveitis (14)     9.4.7 Glaucomas associated with ocular trauma (1)     9.4.8 Glaucomas associated with intraocular tumors (3)     9.4.9 Glaucomas associated with elevated episcleral venous pressure (2)       9.4.10 Glaucomas associated with hemorrhage (1)     9.4.11 Glaucomas following intraocular surgery (0)       9.4.11.1 Ciliary block (malignant) glaucoma (1)       9.4.11.2 Glaucomas in aphakia and pseudophakia (7)       9.4.11.3 Epithelial, fibrous, and endothelial proliferation (0)       9.4.11.4 Glaucomas associated with corneal surgery (3)       9.4.11.5 Glaucomas associated with vitreoretinal surgery (3)     9.4.15 Glaucoma in relation to systemic disease (42)     9.4.20 Other (2) 10 Differential diagnosis e.g. anterior and posterior ischemic optic neuropathy (4) 11 Medical treatment (0)   11.1 General management, indication (6)   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 (5)     11.3.4 Betablocker (4)     11.3.5 Other (0)   11.4 Prostaglandins 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    12.8.1 Without tube implant (13)     12.8.2 With tube implant or other drainage devices (29)     12.8.3 Non-perforating (2)     12.8.4 Using laser (0)     12.8.5 Other (2)     12.8.10 Woundhealing antifibrosis (13)     12.8.11 Complications, endophthalmitis (10)   12.9 Trabeculotomy, goniotomy (10)   12.10 Cyclodestruction (3)   12.11 Cyclodialysis (1)   12.12 Cataract extraction (1)     12.12.1 Intracapsular (0)     12.12.2 Extracapsular (0)     12.12.3 Phacoemulsification (4)   12.14 Combined cataract extraction and glaucoma surgery (0)     12.14.1 Intracapsular (0)     12.14.2 Extracapsular (0)     12.14.3 Phacoemulsification (7)   12.15 Capsulotomy (0)   12.16 Vitrectomy (2)   12.17 Anesthesia (5)   12.20 Other (1) 13 Therapeutic prognosis and outcome (0)   13.1 Prognostic factors (2)   13.2 Outcome (0)     13.2.1 IOP (2)     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 (4) 15 Miscellaneous (23)

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Abstract #69319 Published in IGR 18-1

Pediatric Optical Coherence Tomography in Clinical Practice-Recent Progress

Lee H; Proudlock FA; Gottlob I
Investigative Ophthalmology and Visual Science 2016; 57: OCT69-79

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PURPOSE: Optical coherence tomography (OCT) has revolutionized the diagnosis and management of adult retinal and optic nerve disease. Children were deprived of this technology until the recent development of handheld spectral-domain OCT (HH-SDOCT). In this article, we review the applications of OCT imaging in pediatric ophthalmology. METHODS: This study was a review of the literature. RESULTS: The acquisition and interpretation of pediatric tomograms differ significantly from those for adults, with adjustments needed to account for the shorter axial lengths, higher refractive errors, and ongoing retinal and optic nerve development in the pediatric eye. Handheld SDOCT is increasingly being used as an adjunctive diagnostic tool in retinopathy of prematurity (ROP) and nonaccidental injury (NAI) by providing additional morphologic information that is not normally clinically discernible. The role of HH-SDOCT in streamlining diagnosis in infantile nystagmus syndrome, retinal dystrophies, and degenerations has been established. Optical coherence tomography can also help differentiate between pediatric intraocular tumors, for example, hamartomas and retinoblastoma; monitor tumor progression; and monitor treatment response. In addition, HH-SDOCT is establishing its role as a noninvasive monitoring tool in children affected by optic nerve pathology such as glaucoma, optic nerve atrophy and hypoplasia, optic pathway glioma, and pseudotumor cerebri. CONCLUSIONS: Handheld SDOCT can provide novel insights into the natural history of retinal and optic nerve diseases in young children. For example, in achromatopsia and albinism, in vivo OCT studies have provided evidence of altered but ongoing retinal development in early childhood, which suggests that potentially targeting treatment at an earlier age may optimize visual function by normalizing retinal development.

Clinical and Experimental Sciences Faculty of Medicine, University of Southampton, Southampton, United Kingdom 2University of Leicester Ulverscroft Eye Unit, Leicester, United Kingdom.

Full article

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Classification:

6.9.2.2 Posterior (Part of: 6 Clinical examination methods > 6.9 Computerized image analysis > 6.9.2 Optical coherence tomography)
9.1.2 Juvenile glaucoma (Part of: 9 Clinical forms of glaucomas > 9.1 Developmental glaucomas)

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