This document summarizes a presentation on classifying and managing patients with decreased vision. It discusses evaluating the cause of vision loss by localizing it to a specific part of the visual pathway. Various pathologies are described including ocular media abnormalities, retinopathies, optic neuropathies, chiasmal lesions, and lesions in other parts of the visual pathway. Diagnostic testing and treatment approaches for different conditions are outlined.
This document provides information on anterior ischemic optic neuropathy (AION), which is the most common cause of acute optic neuropathy in older age groups. It can be divided into two types: arteritic AION, which is due to giant cell arteritis; and non-arteritic AION, which makes up most cases. Both types present with sudden painless vision loss and optic disc swelling. Arteritic AION carries a worse prognosis and requires high-dose steroid treatment to prevent loss of vision in the fellow eye. Non-arteritic AION has a variable course but generally a poor rate of recovery without any proven effective treatments.
Neuroretinitis is characterized by optic disc edema and a macular star pattern. It is often idiopathic but can be associated with viral infections. Common symptoms include sudden vision loss without pain. Evaluation involves serological testing and imaging to investigate for infectious etiologies. While it typically resolves spontaneously on its own, specific antibiotic treatment may aid recovery if an infection is identified. The prognosis is generally good with resolution of disc edema within 6-8 weeks and macular star within a year, resulting in restored vision.
Primary optic atrophy occurs due to direct damage to the optic nerve and results in chalky white disc color with well defined margins and normal cupping and vessels. Secondary optic atrophy follows conditions like papilledema that cause swelling first, resulting in a filled cup and dirty white color. Consecutive optic atrophy occurs after other retinal conditions and shows waxy pallor, normal cup and grossly thinned vessels.
The presentation was made under the wise guidance of my professor DR.(prof) P. Rawat (MGMMC & M.Y. HOSPITAL, INDORE).It covers the essential aspects of optic neuritis & optic atrophy.
This document discusses perimetry and visual field testing. It defines visual field as the area that can be seen at a given moment. There are various methods of visual field testing including kinetic and static perimetry. Automated static perimetry tests like Humphrey and Octopus are now commonly used and test the threshold light intensity that can be detected at different points in the visual field. The results are analyzed based on total deviation plots, pattern deviation plots and global indices to detect and monitor glaucomatous visual field defects. Common patterns of visual field defects seen in different conditions are also described.
This document discusses cystoid macular edema (CME), including its pathogenesis, etiology, associated ocular conditions, manifestations, diagnosis and testing. Specifically, it focuses on pseudophakic or Irvine-Gass syndrome CME, which can occur after cataract surgery. The summary discusses how CME results from fluid accumulation in the retina, its appearance on fluorescein angiography, risk factors for pseudophakic CME like vitreous loss during surgery, and how it is diagnosed using techniques like optical coherence tomography.
Marginal corneal ulcer, also known as Mooren's ulcer, is a rare degenerative ulcer that starts at the corneal margin and spreads circumferentially and axially over the cornea. It is a rapidly progressive and painful ulcerative keratitis that can only be diagnosed in the absence of a systemic cause. It must be differentiated from other corneal abnormalities. Benign cases are unilateral, respond well to treatment, and affect elderly people, while malignant cases are bilateral, respond poorly to treatment, and affect younger people in a progressive manner. It is considered an autoimmune disorder associated with infections and various theories about antigen-antibody reactions and molecular mimicry stimulating an autoimmune response.
1. The document provides an overview of approaches to evaluating vision loss, including determining whether it is monocular or binocular and transient or persistent.
2. Examinations should include visual acuity, color vision, visual fields, pupils, and examination of the eyes and optic discs.
3. Causes of transient and acute vision loss are discussed, including optic neuropathies, ischemic events, migraine, and PRES.
4. Progressive vision loss may be due to compressive lesions, glaucoma, or retinal disorders.
This document provides information on anterior ischemic optic neuropathy (AION), which is the most common cause of acute optic neuropathy in older age groups. It can be divided into two types: arteritic AION, which is due to giant cell arteritis; and non-arteritic AION, which makes up most cases. Both types present with sudden painless vision loss and optic disc swelling. Arteritic AION carries a worse prognosis and requires high-dose steroid treatment to prevent loss of vision in the fellow eye. Non-arteritic AION has a variable course but generally a poor rate of recovery without any proven effective treatments.
Neuroretinitis is characterized by optic disc edema and a macular star pattern. It is often idiopathic but can be associated with viral infections. Common symptoms include sudden vision loss without pain. Evaluation involves serological testing and imaging to investigate for infectious etiologies. While it typically resolves spontaneously on its own, specific antibiotic treatment may aid recovery if an infection is identified. The prognosis is generally good with resolution of disc edema within 6-8 weeks and macular star within a year, resulting in restored vision.
Primary optic atrophy occurs due to direct damage to the optic nerve and results in chalky white disc color with well defined margins and normal cupping and vessels. Secondary optic atrophy follows conditions like papilledema that cause swelling first, resulting in a filled cup and dirty white color. Consecutive optic atrophy occurs after other retinal conditions and shows waxy pallor, normal cup and grossly thinned vessels.
The presentation was made under the wise guidance of my professor DR.(prof) P. Rawat (MGMMC & M.Y. HOSPITAL, INDORE).It covers the essential aspects of optic neuritis & optic atrophy.
This document discusses perimetry and visual field testing. It defines visual field as the area that can be seen at a given moment. There are various methods of visual field testing including kinetic and static perimetry. Automated static perimetry tests like Humphrey and Octopus are now commonly used and test the threshold light intensity that can be detected at different points in the visual field. The results are analyzed based on total deviation plots, pattern deviation plots and global indices to detect and monitor glaucomatous visual field defects. Common patterns of visual field defects seen in different conditions are also described.
This document discusses cystoid macular edema (CME), including its pathogenesis, etiology, associated ocular conditions, manifestations, diagnosis and testing. Specifically, it focuses on pseudophakic or Irvine-Gass syndrome CME, which can occur after cataract surgery. The summary discusses how CME results from fluid accumulation in the retina, its appearance on fluorescein angiography, risk factors for pseudophakic CME like vitreous loss during surgery, and how it is diagnosed using techniques like optical coherence tomography.
Marginal corneal ulcer, also known as Mooren's ulcer, is a rare degenerative ulcer that starts at the corneal margin and spreads circumferentially and axially over the cornea. It is a rapidly progressive and painful ulcerative keratitis that can only be diagnosed in the absence of a systemic cause. It must be differentiated from other corneal abnormalities. Benign cases are unilateral, respond well to treatment, and affect elderly people, while malignant cases are bilateral, respond poorly to treatment, and affect younger people in a progressive manner. It is considered an autoimmune disorder associated with infections and various theories about antigen-antibody reactions and molecular mimicry stimulating an autoimmune response.
1. The document provides an overview of approaches to evaluating vision loss, including determining whether it is monocular or binocular and transient or persistent.
2. Examinations should include visual acuity, color vision, visual fields, pupils, and examination of the eyes and optic discs.
3. Causes of transient and acute vision loss are discussed, including optic neuropathies, ischemic events, migraine, and PRES.
4. Progressive vision loss may be due to compressive lesions, glaucoma, or retinal disorders.
This document provides an overview of the diagnostic approach for acute loss of vision. It discusses the three main causes of acute loss of vision and lists specific conditions that can cause acute loss of vision with or without eye pain. For each condition, it describes suggestive clinical findings and the recommended diagnostic approach. Physical examination focuses on a complete eye exam including visual acuity, visual fields, pupil examination, and ophthalmoscopy. The interpretation of exam findings can provide clues to retinal abnormalities, retinal detachment, vein occlusion or artery occlusion. The summary aims to efficiently convey the key information on evaluating and diagnosing different causes of acute loss of vision.
This document discusses glaucomatous optic atrophy (GOA), an irreversible end-stage condition caused by glaucoma that results in severe vision loss. GOA can be caused by uncontrolled primary or secondary glaucoma over many years. The case report describes a patient who developed GOA in one eye due to non-compliance with treatment for chronic open-angle glaucoma, resulting in advanced cupping and pallor of the optic nerve. Aggressive treatment including multiple medications and laser surgery was able to slow progression in the other eye but vision could not be restored in the affected eye. Genetic factors may also contribute to glaucoma types like normal tension glaucoma that can lead to GOA.
This document provides an overview of evaluating and classifying decreased vision. It discusses evaluating the history, color vision, pupils, fundus, visual fields, and ancillary tests. It then classifies causes as macular, retinal, optic neuropathy, chiasmopathy, visual pathway, or occipital cortex. Specific conditions discussed include NAION, Leber's hereditary optic neuropathy, compressive optic neuropathies, toxic/nutritional neuropathies, and lesions of the chiasm, optic tract, lateral geniculate, and occipital cortex.
Ischemic optic neuropathy constitutes one of the major causes of blindness or seriously impaired vision among the middle-aged and elderly population.
Ischemic optic neuropathy is due to acute ischemia of the optic nerve. it can be classified into two, depending upon the part of the optic nerve involved:
1.Anterior ischemic optic neuropathy (AION)
-AION is due to acute ischemia of the front (anterior) part of the optic nerve (also called optic nerve head), which is supplied mainly by the posterior ciliary arteries.
-AION is divided into two types, depending on what causes it:
1.Arteritic AION: This is the most serious type and is due to a disease called giant cell arteritis or temporal arteritis.
2. Non-arteritic AION: This is the usual, most common type, with many different causes but not associated with giant cell arteritis.
2.Posterior ischemic optic neuropathy (PION). -
-PION is a much less common type. It is due to acute ischemia of the back (posterior) part of the optic nerve, located some distance behind the eyeball; this part of the optic nerve is NOT supplied by the posterior ciliary arteries
(Hayreh, 2009)
Normal tension glaucoma, also known as low tension glaucoma, is characterized by open angle glaucoma with typical optic nerve damage but intraocular pressure that is consistently normal or only slightly elevated. It has several risk factors such as older age, female sex, East Asian ethnicity, family history of glaucoma, and thin central corneal thickness. The pathogenesis involves vascular dysfunction, autoimmune mechanisms, vascular inflammation, and genetic mutations. Diagnosis involves a detailed medical history, eye examination, visual field testing, and sometimes additional imaging or blood work. Treatment aims to lower intraocular pressure by 30% using topical eye drops, laser trabeculoplasty, or filtering surgeries along with controlling any underlying vascular problems
Approach to Neurological causes of Vision loss.pptxNeurologyKota
This document provides an overview of the general approach and examination for neurological causes of vision loss. It discusses evaluating for monocular versus binocular visual loss and whether the loss is transient or persistent. The examination involves assessing visual acuity, color vision, visual fields, pupils, eye examination, and funduscopy. For transient monocular visual loss, causes like emboli, vasculitis, and giant cell arteritis are discussed. Persistent monocular loss localizes to the eye or optic nerve. Binocular transient loss is often due to migraines or TIAs, while persistent binocular loss results from retrochiasmal strokes. Progressive vision loss indicates a compressive lesion. Specific conditions like optic neuritis, NA
This document summarizes macular hole and epiretinal membrane. It discusses the vitreous, macula, OCT imaging, pathogenesis and stages of macular hole. It covers risk factors, signs, differential diagnosis and treatment of macular hole including vitrectomy. It also discusses prevalence, risk factors, pathogenesis and components of epiretinal membrane formation.
Corneal ectasias are a group of diseases characterized by corneal thinning and changes in shape. The main types are keratoconus, keratoglobus, and pellucid marginal degeneration. Keratoconus causes a cone-shaped protrusion of the cornea typically in the inferior region. It has a variety of signs on exam including Fleischer rings, Vogt's striae, and corneal scarring. Treatment involves contact lenses, intracorneal ring segments, corneal cross-linking, or transplantation. Keratoglobus is a non-progressive ectasia causing generalized thinning. Pellucid marginal degeneration causes a band of thinning separated from the limbus.
Superficial punctate keratitis by optometry fans site, definition of SPK, causes of superficial punctate keratitis, symptoms of superficial punctate keratitis, treatment of superficial punctate keratitis, management and treatment of SPK
Pseudopapilledema refers to optic disc swelling that is not caused by increased intracranial pressure. It can be caused by conditions like optic nerve head drusen, myelinated nerve fibers, or a small hypermetropic disc. Signs include blurred disc margins and nerve fiber layer swelling. Imaging like ultrasound and FA can help distinguish pseudopapilledema from true papilledema caused by increased intracranial pressure.
Retinitis pigmentosa is a group of hereditary retinal diseases characterized by progressive degeneration of photoreceptors. It begins with night blindness and peripheral vision loss and can progress to tunnel vision or legal blindness. Genetic mutations affecting photoreceptor structure and function or RNA splicing are responsible. On examination, bone spicule pigmentation, vascular attenuation, optic nerve pallor and RPE changes are seen. Diagnosis is confirmed by electroretinography showing photoreceptor dysfunction. There is currently no cure but management focuses on low vision aids, vitamins, and gene or stem cell therapies which are under investigation.
The document discusses visual field testing in glaucoma. It defines the visual field and perimetry, and describes the major types of clinical perimetry tests including full threshold, SITA standard, and SITA fast on Humphrey and normal, dynamic, and TOP strategies on Octopus. It explains parameters such as test patterns, reliability, age-corrected plots, tests like GHT and Bebie curve, and global indices including MD, PSD, SF, and CPSD. The purpose of visual field testing in glaucoma is to detect and monitor disease by measuring light sensitivity across the retinal field.
This document discusses the morphological changes that occur in the optic nerve head and retinal nerve fiber layer in glaucoma. It describes the various patterns of glaucomatous optic nerve damage including focal notching, concentric cupping, saucerization, and advanced cupping. Features that indicate glaucomatous damage include neuroretinal rim thinning, disc hemorrhages, and changes in the retinal vasculature around the optic disc. Evaluation of the optic nerve head is important for early detection of glaucoma before visual field loss occurs.
This document provides an overview of macular holes, including:
- Classification into primary (idiopathic) and secondary holes. Primary holes are caused by vitreous traction while secondary have other causes like trauma.
- Stages of macular hole formation based on Gass classification from early detachment to full thickness hole.
- Surgical treatment involves vitrectomy to relieve traction along with internal limiting membrane peeling which has good outcomes in improving vision.
- Differential diagnosis includes epiretinal membranes and pseudoholes which have different presentations and prognoses.
This document discusses various causes of optic disc edema. It begins by defining disc edema as swelling of the optic disc that can be caused by active or passive factors other than papilledema. Several pseudoedemas are described including drusen, myelinated fibers, tilted discs, and hypoplastic discs. True disc edemas can result from inflammation, vascular issues like CRVO, infiltrative diseases, or papilledema from increased intracranial pressure. Papilledema is usually bilateral non-inflammatory swelling caused by conditions that raise ICP like brain tumors, infections, pseudotumor cerebri, or venous sinus thrombosis. The pathogenesis and features of optic neuritis, multiple sclerosis, and papille
Age-related macular degeneration (AMD) is a leading cause of blindness that results from thickening of Bruch's membrane with age, interfering with metabolism in the retinal pigment epithelium (RPE) and photoreceptors. This causes deposits called drusen that damage the overlying RPE and underlying tissue. There are two forms: dry AMD involves gradual RPE and photoreceptor atrophy, while wet AMD features choroidal neovascularization that leaks fluid and blood, causing rapid vision loss if untreated. Risk factors include age, genetics, smoking, and diet.
This document discusses various causes of acute visual loss, categorizing them as ocular or non-ocular. In the ocular category, it describes common causes such as media opacities, retinal issues including vascular occlusions, and optic nerve disorders. It provides details on evaluating and treating specific conditions like acute angle closure glaucoma, retinal detachment, macular diseases, and ischemic optic neuropathies. It emphasizes that many ocular causes of acute visual loss require prompt diagnosis and treatment to prevent permanent vision loss. Non-ocular causes discussed include stroke and functional visual loss.
This document discusses the effects of diabetes on the eye. It begins with an introduction to diabetes mellitus and its long-term damaging effects on organs. It then covers the two main types of diabetes and their characteristics. The document discusses the pathogenesis of diabetic retinopathy and how high blood glucose damages blood vessels in the eye. It provides a detailed overview of the stages of diabetic retinopathy from mild non-proliferative to proliferative and potential vision loss outcomes. Management strategies like glucose control, laser therapy, anti-VEGF drugs, and vitrectomy are summarized.
Laser therapy can be used to treat glaucoma by destroying the ciliary body to reduce fluid production or opening the drainage angle. Cyclophotocoagulation uses lasers to destroy the ciliary body. It is indicated for pain from severe glaucoma when vision is poor, inability to have surgery, or failed prior surgeries. Postoperative care includes patching, atropine, steroids, and tapering medications except miotics. Complications can include rejection, bleeding, cataracts, or sympathetic ophthalmia.
This document summarizes various optic nerve head (ONH) abnormalities, causes of ONH swelling, and lesions that can occur at the chiasm and retrochiasmally. It describes conditions such as optic disc coloboma, tilted disc, myelinated nerve fibers, optic disc drusen, papilledema, anterior ischemic optic neuropathy, pituitary tumors, meningiomas, craniopharyngiomas, aneurysms, and gliomas; and how these present with features like visual field defects, optic atrophy, and visual loss. Lesions are discussed based on their location in the optic nerve, chiasm, optic tract, lateral geniculate nucleus, temporal lobe, parietal lobe, and occ
Optic nerve and retinal diseases are described including optic neuritis, anterior ischemic optic neuropathy, central retinal vein occlusion, central retinal artery occlusion, and age-related macular degeneration. Optic neuritis causes eye pain, vision loss, and color vision changes. Central retinal vein occlusion blocks the main vein draining the retina causing hemorrhages and macular edema. Central retinal artery occlusion involves sudden vision loss from blockage of the artery supplying the retina. Age-related macular degeneration is the leading cause of vision loss in older adults and involves the degeneration of the macula.
The document discusses iridocorneal endothelial (ICE) syndrome, a rare disorder characterized by abnormalities of the corneal endothelium and iris that can cause corneal decompensation and glaucoma. ICE syndrome has three clinical variants (iris nevus/Cogan-Reese syndrome, Chandler syndrome, and essential/progressive iris atrophy) that are characterized by different degrees of iris atrophy. The pathogenesis involves proliferation of abnormal endothelial cells that migrate onto the trabecular meshwork and iris. Investigations include gonioscopy, ultrasound biomicroscopy, and specular microscopy of the corneal endothelium. Treatment involves medications and surgeries to manage glaucoma and corneal edema.
This document provides an overview of the diagnostic approach for acute loss of vision. It discusses the three main causes of acute loss of vision and lists specific conditions that can cause acute loss of vision with or without eye pain. For each condition, it describes suggestive clinical findings and the recommended diagnostic approach. Physical examination focuses on a complete eye exam including visual acuity, visual fields, pupil examination, and ophthalmoscopy. The interpretation of exam findings can provide clues to retinal abnormalities, retinal detachment, vein occlusion or artery occlusion. The summary aims to efficiently convey the key information on evaluating and diagnosing different causes of acute loss of vision.
This document discusses glaucomatous optic atrophy (GOA), an irreversible end-stage condition caused by glaucoma that results in severe vision loss. GOA can be caused by uncontrolled primary or secondary glaucoma over many years. The case report describes a patient who developed GOA in one eye due to non-compliance with treatment for chronic open-angle glaucoma, resulting in advanced cupping and pallor of the optic nerve. Aggressive treatment including multiple medications and laser surgery was able to slow progression in the other eye but vision could not be restored in the affected eye. Genetic factors may also contribute to glaucoma types like normal tension glaucoma that can lead to GOA.
This document provides an overview of evaluating and classifying decreased vision. It discusses evaluating the history, color vision, pupils, fundus, visual fields, and ancillary tests. It then classifies causes as macular, retinal, optic neuropathy, chiasmopathy, visual pathway, or occipital cortex. Specific conditions discussed include NAION, Leber's hereditary optic neuropathy, compressive optic neuropathies, toxic/nutritional neuropathies, and lesions of the chiasm, optic tract, lateral geniculate, and occipital cortex.
Ischemic optic neuropathy constitutes one of the major causes of blindness or seriously impaired vision among the middle-aged and elderly population.
Ischemic optic neuropathy is due to acute ischemia of the optic nerve. it can be classified into two, depending upon the part of the optic nerve involved:
1.Anterior ischemic optic neuropathy (AION)
-AION is due to acute ischemia of the front (anterior) part of the optic nerve (also called optic nerve head), which is supplied mainly by the posterior ciliary arteries.
-AION is divided into two types, depending on what causes it:
1.Arteritic AION: This is the most serious type and is due to a disease called giant cell arteritis or temporal arteritis.
2. Non-arteritic AION: This is the usual, most common type, with many different causes but not associated with giant cell arteritis.
2.Posterior ischemic optic neuropathy (PION). -
-PION is a much less common type. It is due to acute ischemia of the back (posterior) part of the optic nerve, located some distance behind the eyeball; this part of the optic nerve is NOT supplied by the posterior ciliary arteries
(Hayreh, 2009)
Normal tension glaucoma, also known as low tension glaucoma, is characterized by open angle glaucoma with typical optic nerve damage but intraocular pressure that is consistently normal or only slightly elevated. It has several risk factors such as older age, female sex, East Asian ethnicity, family history of glaucoma, and thin central corneal thickness. The pathogenesis involves vascular dysfunction, autoimmune mechanisms, vascular inflammation, and genetic mutations. Diagnosis involves a detailed medical history, eye examination, visual field testing, and sometimes additional imaging or blood work. Treatment aims to lower intraocular pressure by 30% using topical eye drops, laser trabeculoplasty, or filtering surgeries along with controlling any underlying vascular problems
Approach to Neurological causes of Vision loss.pptxNeurologyKota
This document provides an overview of the general approach and examination for neurological causes of vision loss. It discusses evaluating for monocular versus binocular visual loss and whether the loss is transient or persistent. The examination involves assessing visual acuity, color vision, visual fields, pupils, eye examination, and funduscopy. For transient monocular visual loss, causes like emboli, vasculitis, and giant cell arteritis are discussed. Persistent monocular loss localizes to the eye or optic nerve. Binocular transient loss is often due to migraines or TIAs, while persistent binocular loss results from retrochiasmal strokes. Progressive vision loss indicates a compressive lesion. Specific conditions like optic neuritis, NA
This document summarizes macular hole and epiretinal membrane. It discusses the vitreous, macula, OCT imaging, pathogenesis and stages of macular hole. It covers risk factors, signs, differential diagnosis and treatment of macular hole including vitrectomy. It also discusses prevalence, risk factors, pathogenesis and components of epiretinal membrane formation.
Corneal ectasias are a group of diseases characterized by corneal thinning and changes in shape. The main types are keratoconus, keratoglobus, and pellucid marginal degeneration. Keratoconus causes a cone-shaped protrusion of the cornea typically in the inferior region. It has a variety of signs on exam including Fleischer rings, Vogt's striae, and corneal scarring. Treatment involves contact lenses, intracorneal ring segments, corneal cross-linking, or transplantation. Keratoglobus is a non-progressive ectasia causing generalized thinning. Pellucid marginal degeneration causes a band of thinning separated from the limbus.
Superficial punctate keratitis by optometry fans site, definition of SPK, causes of superficial punctate keratitis, symptoms of superficial punctate keratitis, treatment of superficial punctate keratitis, management and treatment of SPK
Pseudopapilledema refers to optic disc swelling that is not caused by increased intracranial pressure. It can be caused by conditions like optic nerve head drusen, myelinated nerve fibers, or a small hypermetropic disc. Signs include blurred disc margins and nerve fiber layer swelling. Imaging like ultrasound and FA can help distinguish pseudopapilledema from true papilledema caused by increased intracranial pressure.
Retinitis pigmentosa is a group of hereditary retinal diseases characterized by progressive degeneration of photoreceptors. It begins with night blindness and peripheral vision loss and can progress to tunnel vision or legal blindness. Genetic mutations affecting photoreceptor structure and function or RNA splicing are responsible. On examination, bone spicule pigmentation, vascular attenuation, optic nerve pallor and RPE changes are seen. Diagnosis is confirmed by electroretinography showing photoreceptor dysfunction. There is currently no cure but management focuses on low vision aids, vitamins, and gene or stem cell therapies which are under investigation.
The document discusses visual field testing in glaucoma. It defines the visual field and perimetry, and describes the major types of clinical perimetry tests including full threshold, SITA standard, and SITA fast on Humphrey and normal, dynamic, and TOP strategies on Octopus. It explains parameters such as test patterns, reliability, age-corrected plots, tests like GHT and Bebie curve, and global indices including MD, PSD, SF, and CPSD. The purpose of visual field testing in glaucoma is to detect and monitor disease by measuring light sensitivity across the retinal field.
This document discusses the morphological changes that occur in the optic nerve head and retinal nerve fiber layer in glaucoma. It describes the various patterns of glaucomatous optic nerve damage including focal notching, concentric cupping, saucerization, and advanced cupping. Features that indicate glaucomatous damage include neuroretinal rim thinning, disc hemorrhages, and changes in the retinal vasculature around the optic disc. Evaluation of the optic nerve head is important for early detection of glaucoma before visual field loss occurs.
This document provides an overview of macular holes, including:
- Classification into primary (idiopathic) and secondary holes. Primary holes are caused by vitreous traction while secondary have other causes like trauma.
- Stages of macular hole formation based on Gass classification from early detachment to full thickness hole.
- Surgical treatment involves vitrectomy to relieve traction along with internal limiting membrane peeling which has good outcomes in improving vision.
- Differential diagnosis includes epiretinal membranes and pseudoholes which have different presentations and prognoses.
This document discusses various causes of optic disc edema. It begins by defining disc edema as swelling of the optic disc that can be caused by active or passive factors other than papilledema. Several pseudoedemas are described including drusen, myelinated fibers, tilted discs, and hypoplastic discs. True disc edemas can result from inflammation, vascular issues like CRVO, infiltrative diseases, or papilledema from increased intracranial pressure. Papilledema is usually bilateral non-inflammatory swelling caused by conditions that raise ICP like brain tumors, infections, pseudotumor cerebri, or venous sinus thrombosis. The pathogenesis and features of optic neuritis, multiple sclerosis, and papille
Age-related macular degeneration (AMD) is a leading cause of blindness that results from thickening of Bruch's membrane with age, interfering with metabolism in the retinal pigment epithelium (RPE) and photoreceptors. This causes deposits called drusen that damage the overlying RPE and underlying tissue. There are two forms: dry AMD involves gradual RPE and photoreceptor atrophy, while wet AMD features choroidal neovascularization that leaks fluid and blood, causing rapid vision loss if untreated. Risk factors include age, genetics, smoking, and diet.
This document discusses various causes of acute visual loss, categorizing them as ocular or non-ocular. In the ocular category, it describes common causes such as media opacities, retinal issues including vascular occlusions, and optic nerve disorders. It provides details on evaluating and treating specific conditions like acute angle closure glaucoma, retinal detachment, macular diseases, and ischemic optic neuropathies. It emphasizes that many ocular causes of acute visual loss require prompt diagnosis and treatment to prevent permanent vision loss. Non-ocular causes discussed include stroke and functional visual loss.
This document discusses the effects of diabetes on the eye. It begins with an introduction to diabetes mellitus and its long-term damaging effects on organs. It then covers the two main types of diabetes and their characteristics. The document discusses the pathogenesis of diabetic retinopathy and how high blood glucose damages blood vessels in the eye. It provides a detailed overview of the stages of diabetic retinopathy from mild non-proliferative to proliferative and potential vision loss outcomes. Management strategies like glucose control, laser therapy, anti-VEGF drugs, and vitrectomy are summarized.
Laser therapy can be used to treat glaucoma by destroying the ciliary body to reduce fluid production or opening the drainage angle. Cyclophotocoagulation uses lasers to destroy the ciliary body. It is indicated for pain from severe glaucoma when vision is poor, inability to have surgery, or failed prior surgeries. Postoperative care includes patching, atropine, steroids, and tapering medications except miotics. Complications can include rejection, bleeding, cataracts, or sympathetic ophthalmia.
This document summarizes various optic nerve head (ONH) abnormalities, causes of ONH swelling, and lesions that can occur at the chiasm and retrochiasmally. It describes conditions such as optic disc coloboma, tilted disc, myelinated nerve fibers, optic disc drusen, papilledema, anterior ischemic optic neuropathy, pituitary tumors, meningiomas, craniopharyngiomas, aneurysms, and gliomas; and how these present with features like visual field defects, optic atrophy, and visual loss. Lesions are discussed based on their location in the optic nerve, chiasm, optic tract, lateral geniculate nucleus, temporal lobe, parietal lobe, and occ
Optic nerve and retinal diseases are described including optic neuritis, anterior ischemic optic neuropathy, central retinal vein occlusion, central retinal artery occlusion, and age-related macular degeneration. Optic neuritis causes eye pain, vision loss, and color vision changes. Central retinal vein occlusion blocks the main vein draining the retina causing hemorrhages and macular edema. Central retinal artery occlusion involves sudden vision loss from blockage of the artery supplying the retina. Age-related macular degeneration is the leading cause of vision loss in older adults and involves the degeneration of the macula.
The document discusses iridocorneal endothelial (ICE) syndrome, a rare disorder characterized by abnormalities of the corneal endothelium and iris that can cause corneal decompensation and glaucoma. ICE syndrome has three clinical variants (iris nevus/Cogan-Reese syndrome, Chandler syndrome, and essential/progressive iris atrophy) that are characterized by different degrees of iris atrophy. The pathogenesis involves proliferation of abnormal endothelial cells that migrate onto the trabecular meshwork and iris. Investigations include gonioscopy, ultrasound biomicroscopy, and specular microscopy of the corneal endothelium. Treatment involves medications and surgeries to manage glaucoma and corneal edema.
Optic atrophy refers to damage to the optic nerve resulting in loss of retinal ganglion cells and their axons. It can be primary, secondary, consecutive, or glaucomatous. Primary optic atrophy results directly from injury to the retinal ganglion cell or axon. Secondary optic atrophy occurs due to severe disc edema, inflammation, or long-standing orbital inflammation. Consecutive optic atrophy is due to retinal disease destroying ganglion cells. Glaucomatous optic atrophy is characterized by cupping and excavation of the optic disc. Toxic or nutritional optic neuropathies can result from substance exposure, deficiencies, or abuse and present with central vision loss, but are sometimes reversible if the cause
This document provides an overview of the anatomy and clinical assessment of the optic nerve in 3 paragraphs:
1) It describes the anatomy of the optic nerve, including its origin from the ganglion cells and path from the optic disc to the optic chiasm. It is composed of over 1 million axons and is divided into intraocular, intraorbital, intracanalicular, and intracranial portions.
2) Clinical assessment of the optic nerve involves testing visual acuity, color vision, visual fields, and the pupillary light reflex. Signs of optic nerve pathology include an afferent pupillary defect.
3) Different pathologies like papilledema, optic neuritis, and optic
This document provides an overview of vitreoretinal diseases and the anatomy of the vitreous and retina. It discusses examination of the normal eye, symptoms of vitreoretinal disorders, and abnormal fundus features seen on examination. Specific conditions covered include retinal detachment, age-related macular degeneration, diabetic retinopathy, and effects of systemic diseases like hypertension and AIDS. Management approaches for various vitreoretinal diseases are also summarized.
1) The document describes various normal structures and lesions of the retina and optic nerve head. It discusses the anatomy of the retina and defines different regions.
2) Pathological conditions are described such as papilledema, optic neuritis, retinal hemorrhages, exudates, neovascularization, and atrophy. Imaging findings for various diseases are shown.
3) Additional sections cover lesions of the vitreous and fundus, including hemorrhages, exudates, vascular abnormalities and pathological structures. Various normal variations and congenital anomalies are also detailed.
20-eye-diseases.ppt diseae\ses of the eyeMamataStephen
This document provides a summary of 20 common eye diseases organized by anatomical location. It discusses diseases of the lids and lashes, cornea, tear film, conjunctiva, lacrimal system, crystalline lens, and retina. For each disease it identifies characteristics, clinical presentations, and testing. The goal is to familiarize readers with these common eye conditions and examinations.
This document discusses various metabolic disorders and their ocular manifestations. It begins by introducing metabolic disorders and how they are generally inherited. It then discusses specific disorders affecting amino acid metabolism, carbohydrate metabolism, and other pathways. For each disorder, it describes the genetic cause, systemic findings, and relevant ocular manifestations such as corneal opacities, cataracts, retinal degeneration, and more. Overall, the document provides an overview of how inborn errors of metabolism can impact eye health through various pathological mechanisms and biochemical lesions.
This document discusses various congenital optic disc anomalies including optic nerve hypoplasia, megalopapilla, congenital tilted disc syndrome, optic disc coloboma, optic disc pit, optic disc drusen, and hyaloid system remnants. It describes the characteristic clinical features, pathogenesis, associated ocular and systemic findings, differential diagnosis, and treatment of each condition. Congenital optic disc anomalies can cause visual impairment ranging from no light perception to normal vision and may be associated with neurological or systemic abnormalities. Accurate diagnosis is important for appropriate patient management and screening for related conditions.
Congenital retinal anomalies can arise from developmental defects, vascular abnormalities, infections, tumors or trauma. Clinical presentation depends on laterality and extent of vision loss. Examination may reveal colobomas, retinal folds, persistent fetal vasculature or lacunae indicative of conditions like Aicardi syndrome. Retinopathy of prematurity is a major cause of vision loss in premature infants and progresses through stages from demarcation lines to retinal detachment. Infectious etiologies can cause chorioretinitis from viruses like cytomegalovirus and parasites including toxoplasmosis. Prompt treatment is aimed at the underlying cause and prevention of complications affecting vision.
Gradual vision loss is caused by many conditions that develop over weeks to years. The most common causes are age-related macular degeneration, cataracts, glaucoma, diabetic retinopathy, and refractive errors. A thorough history and eye exam can help identify the cause by examining symptoms, visual acuity, the retina, and optic nerve. Treatment depends on the specific condition but may include eye drops, laser therapy, surgery, or lifestyle changes.
Optic atrophy is the degeneration of the optic nerve that occurs when the ganglion cells and axons in the retina are damaged. It can be classified clinically, etiologically, and anatomically. Clinically, it is classified as primary, secondary, consecutive, cavernous, or segmental based on ophthalmoscopic features. Causes include diseases of the visual pathways, swelling/congestion of the optic nerve head, destruction of ganglion cells, or axonal degeneration without glial proliferation. Etiologically, it can be hereditary, consecutive, vascular, toxic, metabolic, demyelinating, pressure-related, post-inflammatory, or traumatic. Anatomically it is classified
- Orbital cellulitis is a serious infection of the orbital tissues that does not involve the globe itself. It is most commonly caused by bacterial infection spreading from the paranasal sinuses.
- Physical examination includes assessing vision, eye movements, proptosis, pupil function, and examining the orbit, eyelids and anterior/posterior segments for signs of infection or complications.
- Early diagnosis and treatment with intravenous antibiotics is important to prevent vision loss or life-threatening intracranial infections.
Retinitis pigmentosa is a group of inherited retinal diseases characterized by progressive degeneration of the photoreceptors. It initially affects rods, resulting in night blindness and peripheral vision loss, and later involves cones leading to tunnel vision. Symptoms include nyctalopia and peripheral field defects. Signs include bone spicule pigmentation, arteriolar attenuation, and disc pallor. It can be inherited in autosomal dominant, recessive or X-linked patterns. Investigations include electroretinography to detect photoreceptor dysfunction and optical coherence tomography. There is currently no cure or treatment to stop progression.
Myopia, or nearsightedness, occurs when the eye focuses light rays in front of the retina. It has several causes including increased axial length of the eyeball and increased curvature of the cornea or lens. Pathological myopia is a degenerative form associated with rapid axial elongation and vision loss. It can lead to retinal detachment, choroidal neovascularization, and other complications. Treatment involves optical correction with glasses or contacts, as well as preventative measures like atropine drops to slow progression. Surgery such as LASIK may also be used in some cases.
AGE RELATED MACULAR DEGRNERATION(ARMD).pdfAwais irshad
Overview of functioning of eye
• What is macula and it’s function
• Age related macular degeneration
• Pathophysiology of AMD
• Risk factors
• Types of AMD
• Signs and symptoms of AMD
• Diagnosis of AMD
• Treatment and management of AMD
Macula lutea is the specialized area of retina located at the posterior pole.
• It contains fovea Centralis, which is much specialized and sensitive area in
the centre of Macula
• Foveola is the shining pit in the central floor of the fovea ,contains a great
number of cones(light sensitive photoreceptors) responsible for bright
vision
• Macula is present in the centre of retina and is specialized for the central
vision, pinpoint vision , i.e in reading ,driving etc
• While the peripheral retina Gives the side images not the pin point images
Orientation,history taking and examinatio.pptsultanovasits
The document outlines an orientation course for ophthalmology residents that covers various topics including history taking, examination techniques, common diseases and emergencies. It details the objectives of the course, components such as lectures and clinical sessions, assessment methods, recommended textbooks and electronic resources. Key examination techniques discussed include visual acuity testing, external eye examination, motility evaluation, slit lamp biomicroscopy, tonometry and ophthalmoscopy.
Similar to THE PATIENT WITH DECREASED VISION Classification and Management by Iddi.pptx (20)
Depositions and Degenerations of Conjuctiva and Cornea.docxIddi Ndyabawe
This document provides an overview of degenerative changes that can occur in the conjunctiva, cornea, and sclera. It describes age-related changes such as thinning and loss of transparency in the conjunctiva. Specific conditions discussed include pinguecula, pterygium, conjunctival concretions, and conjunctivochalasis. Corneal degenerations covered include Coats white ring, spheroidal degeneration, iron deposition, and calcific band keratopathy. The document also briefly outlines degenerations of the sclera and endothelium and their causes, signs, and treatments.
Central corneal ulcers are local epithelial defects with underlying corneal tissue degradation or inflammation. Common causes include bacterial and fungal infections related to contact lens use or exposure. Diagnosis involves history, exam noting epithelial loss and infiltrate size/density, and corneal cultures. Treatment begins with frequent topical fluoroquinolone or fortified antibiotics based on culture results. Referral is needed if unable to culture, no response to treatment, progressive lesion, or atypical infiltrate. Daily follow up is required until the lesion stabilizes, indicated by epithelial healing and resolution of symptoms and signs of infection.
1. Acute viral conjunctivitis is caused primarily by adenovirus and presents as a bilateral red eye with watery discharge. It affects both children and adults and has no genetic predisposition.
2. Diagnosis is based on symptoms and physical exam findings like injection and follicular reaction. Point of care immunoassays can rapidly detect adenovirus but culture and PCR are also options.
3. Treatment focuses on supportive care with artificial tears since antiviral medications are generally not effective. Most cases resolve spontaneously in 10 days but some may develop subepithelial infiltrates requiring follow up.
The science of refractive surgery by Dr. Iddi.pptxIddi Ndyabawe
This document provides an overview of refractive surgery and corneal optics. It discusses topics such as corneal biomechanics, imaging, and the effects of different keratorefractive surgical procedures. Laser refractive techniques like LASIK, PRK, and conductive keratoplasty are outlined. The importance of preoperative imaging and wavefront analysis is emphasized to detect contraindications like keratoconus and optimize outcomes. Key principles of excimer laser photoablation and factors influencing postoperative visual quality are also summarized.
Surgeries for glaucoma An Overview by Dr. Iddi.pptxIddi Ndyabawe
This document provides an overview of surgeries for glaucoma, including their evolution and mechanisms. It discusses non-filtering surgeries like iridotomy and trabeculotomy, as well as filtering surgeries like trabeculectomy. The document also covers combined cataract extraction and trabeculectomy, cyclo-destructive procedures, and the use of surgery in specific glaucoma subtypes. It aims to educate physicians on the various surgical options available to treat glaucoma.
This document summarizes a presentation on orbital surgery. It discusses various surgical approaches to the orbit including lid crease incisions, lateral orbitotomies, and endoscopic decompression. It also covers orbital decompression techniques like superior, medial, inferior and lateral decompression to treat conditions like Graves' orbitopathy. Potential complications of orbital surgery are discussed such as diplopia, optic neuropathy, and hypoesthesia, as well as techniques to avoid complications by careful patient evaluation, approach selection, exposure and hemostasis.
Lasers are commonly used in the treatment of glaucoma. ND:YAG lasers are well suited for procedures like peripheral iridotomy due to their wavelength of 1064nm which is absorbed by pigment in the iris but transmits through aqueous and lens. Laser trabeculoplasty procedures like ALT and more selectively SLT are used to lower intraocular pressure by modifying outflow pathways in the trabecular meshwork. Other laser applications include iridoplasty/gonioplasty to surgically treat angle closure glaucoma and malignant glaucoma, as well as revision of failed glaucoma surgeries through techniques like suturolysis. While highly effective, lasers require precision to avoid
Introduction to ocular trauma Dr. Iddi Slides.pptxIddi Ndyabawe
This document provides an introduction to ocular trauma, including common causes, populations affected, assessment of injuries, and management principles. It discusses various types of injuries like mechanical, chemical, thermal, radiation and injuries from organic and non-organic materials. Modes of injury include tools/machinery, assaults, sports activities and war injuries. Assessment involves history, examination, and investigations like x-ray and CT. Injuries can range from mild to severe, with moderate and severe cases threatening vision.
This document summarizes corneal collagen shrinkage and collagen crosslinking techniques. It discusses how collagen shrinkage was initially used to treat keratoconus through heating methods but had limitations due to necrosis. Collagen crosslinking was developed to strengthen corneal collagen through riboflavin and UV light exposure based on the Dresden Protocol. Variations including accelerated and customized protocols aim to treat thinner corneas and focal disease. While generally safe and effective for keratoconus, complications can include haze, infection, and continued progression requiring proper technique. New applications investigate refractive corrections and other corneal conditions.
Approach to a patient with ectropion, entropion, symblepharon.pptxIddi Ndyabawe
This document discusses approaches to treating ectropion, entropion, and symblepharon. It describes the anatomy and causes of ectropion and entropion, including involutional, cicatricial, paralytis, and congenital types. Clinical features, grading scales, and surgical management techniques are outlined for different types and severities of ectropion and entropion. Symblepharon is defined as an adhesion between conjunctival surfaces, with treatment involving conjunctival grafts or flaps.
This document outlines the procedure for enucleation to treat retinoblastoma. There are three main goals: save the child's life, keep the eye, and preserve vision. Enucleation is indicated for advanced intraocular retinoblastoma, when saving the globe has failed, or for a phthisical eye after chemotherapy. The procedure involves 30 steps, including confirming the correct eye, administering anesthesia, cutting the extraocular muscles, removing the globe, and closing the conjunctiva. Post-operative care includes antibiotics, steroids, checking for high-risk histopathology findings, and fitting an ocular prosthesis.
This document provides a 10 step standard operating procedure for cleansing and caring for ophthalmic surgical instruments:
1) Wipe off blood and debris using gauze and saline.
2) Soak instruments in jik water for 5 minutes to disinfect.
3) Clean instruments using soapy water and a soft toothbrush.
4) Rinse instruments with distilled water to remove soap and dry thoroughly before storage.
5) Lubricate hinged instruments to prevent corrosion.
Conjunctival lymphoma is a type of extranodal lymphoma that originates in the conjunctiva without involving lymph nodes. It represents about 2% of extranodal lymphomas and 8% of all conjunctival tumors. Risk factors include immunosuppression and chronic infections. Symptoms include a painless pink conjunctival mass. Diagnosis involves biopsy and imaging to identify the lymphoma and rule out systemic involvement. Treatment options include surgical excision when possible followed by chemotherapy, radiation, or monoclonal antibodies. Patients require lifelong follow-up to monitor for recurrence or progression to systemic lymphoma, which occurs in up to 28% of cases over 10 years.
1. Herpes simplex virus (HSV) and varicella zoster virus (VZV) can cause ocular infections and disease. HSV commonly causes blepharoconjunctivitis but can also lead to recurrent epithelial, stromal, or endothelial keratitis. VZV reactivation causes herpes zoster ophthalmicus (HZO), presenting with rash in the V1 dermatome and potentially causing keratitis.
2. HSV keratitis presentations include punctate epithelial erosions, dendritic ulcers, or stromal infiltrates and opacities. Treatment involves topical antivirals like acyclovir and topical steroids. Recurrent disease may
Episcleritis is a benign inflammation of the outer layer of the eyeball (episclera) that causes redness and mild discomfort. It typically affects young adults and has no known cause, though it can be associated with conditions like gout. Scleritis is a more serious inflammation of the white part of the eyeball (sclera) that can cause vision loss if untreated. It usually occurs in older patients and has been linked to autoimmune disorders and infections. Scleritis is classified based on location and severity, with necrotizing forms requiring strong steroids or immunosuppressants to prevent complications like scleral thinning. Blue sclera is an asymptomatic condition where the sclera
1. Blepharitis is an inflammation of the eyelid margins that can be seborrheic, staphylococcal, mixed, or parasitic in nature. Seborrheic blepharitis involves scales on the lid margins and lashes falling out easily. Staphylococcal blepharitis features ulcers and crusts on the lid margins that can lead to complications like conjunctivitis if not treated promptly with antibiotic ointment and eyedrops. Posterior blepharitis or meibomitis presents with foam-like secretions and clogged glands, treated by expressing the glands and using antibiotics. Parasitic blepharitis involves nits
Ophthalmia neonatorum is inflammation of the conjunctiva in infants less than 30 days old, usually caused by infections transmitted during or after birth. Common causes include gonorrhea, chlamydia, staph, and strep bacteria. Left untreated, gonorrheal ophthalmia can lead to corneal ulceration and blindness. Prophylactic treatment with antibiotics like tetracycline or erythromycin ointment immediately after birth can prevent most cases. For diagnosed infections, treatment involves topical antibiotics, antivirals, or antiseptics as well as systemic antibiotics depending on the causative agent. Prompt and complete treatment is important to resolve symptoms and prevent complications.
1. Xerophthalmia refers to all ocular manifestations of vitamin A deficiency, including structural changes to the conjunctiva, cornea, and retina as well as disorders of retinal rod and cone function.
2. It is caused by dietary vitamin A deficiency or impaired absorption and often accompanies protein-energy malnutrition and infections.
3. The WHO classification includes stages from night blindness to corneal scarring. Treatment involves local eye care, high-dose vitamin A supplementation, and treating underlying illnesses.
This document discusses ocular surface squamous neoplasia (OSSN), a spectrum of conjunctival and corneal epithelial dysplasia ranging from intraepithelial dysplasia to invasive squamous cell carcinoma. It affects mostly older males with a history of sun exposure or smoking. Diagnosis involves examining the eyes for white or gray lesions and confirming with biopsy. Treatment is complete surgical excision to prevent recurrence, with referral to an ocular oncology service for invasive or difficult to remove cases.
COPD Treatment in Ghatkopar,Mumbai. Dr Kumar DoshiDr Kumar Doshi
Are you or a loved one affected by Chronic Obstructive Pulmonary Disease (COPD)? Discover comprehensive and advanced treatment options with Dr. Kumar Doshi, a preeminent COPD specialist based in Ghatkopar, Mumbai.
Dr. Kumar Doshi is dedicated to delivering the highest standard of care for COPD patients. Whether you are seeking a diagnosis, a second opinion, or exploring new treatment avenues, this presentation will guide you through the exceptional services available at his practice in Ghatkopar, Mumbai.
R3 Stem Cell Therapy: A New Hope for Women with Ovarian FailureR3 Stem Cell
Discover the groundbreaking advancements in stem cell therapy by R3 Stem Cell, offering new hope for women with ovarian failure. This innovative treatment aims to restore ovarian function, improve fertility, and enhance overall well-being, revolutionizing reproductive health for women worldwide.
Healthy Eating Habits:
Understanding Nutrition Labels: Teaches how to read and interpret food labels, focusing on serving sizes, calorie intake, and nutrients to limit or include.
Tips for Healthy Eating: Offers practical advice such as incorporating a variety of foods, practicing moderation, staying hydrated, and eating mindfully.
Benefits of Regular Exercise:
Physical Benefits: Discusses how exercise aids in weight management, muscle and bone health, cardiovascular health, and flexibility.
Mental Benefits: Explains the psychological advantages, including stress reduction, improved mood, and better sleep.
Tips for Staying Active:
Encourages consistency, variety in exercises, setting realistic goals, and finding enjoyable activities to maintain motivation.
Maintaining a Balanced Lifestyle:
Integrating Nutrition and Exercise: Suggests meal planning and incorporating physical activity into daily routines.
Monitoring Progress: Recommends tracking food intake and exercise, regular health check-ups, and provides tips for achieving balance, such as getting sufficient sleep, managing stress, and staying socially active.
We are one of the top Massage Spa Ajman Our highly skilled, experienced, and certified massage therapists from different corners of the world are committed to serving you with a soothing and relaxing experience. Luxuriate yourself at our spas in Sharjah and Ajman, which are indeed enriched with an ambiance of relaxation and tranquility. We could confidently claim that we are one of the most affordable Spa Ajman and Sharjah as well, where you can book the massage session of your choice for just 99 AED at any time as we are open 24 hours a day, 7 days a week.
Visit : https://massagespaajman.com/
Call : 052 987 1315
Letter to MREC - application to conduct studyAzreen Aj
Application to conduct study on research title 'Awareness and knowledge of oral cancer and precancer among dental outpatient in Klinik Pergigian Merlimau, Melaka'
Exploring the Benefits of Binaural Hearing: Why Two Hearing Aids Are Better T...Ear Solutions (ESPL)
Binaural hearing using two hearing aids instead of one offers numerous advantages, including improved sound localization, enhanced sound quality, better speech understanding in noise, reduced listening effort, and greater overall satisfaction. By leveraging the brain’s natural ability to process sound from both ears, binaural hearing aids provide a more balanced, clear, and comfortable hearing experience. If you or a loved one is considering hearing aids, consult with a hearing care professional at Ear Solutions hearing aid clinic in Mumbai to explore the benefits of binaural hearing and determine the best solution for your hearing needs. Embracing binaural hearing can lead to a richer, more engaging auditory experience and significantly improve your quality of life.
This particular slides consist of- what is Pneumothorax,what are it's causes and it's effect on body, risk factors, symptoms,complications, diagnosis and role of physiotherapy in it.
This slide is very helpful for physiotherapy students and also for other medical and healthcare students.
Here is a summary of Pneumothorax:
Pneumothorax, also known as a collapsed lung, is a condition that occurs when air leaks into the space between the lung and chest wall. This air buildup puts pressure on the lung, preventing it from expanding fully when you breathe. A pneumothorax can cause a complete or partial collapse of the lung.
At Apollo Hospital, Lucknow, U.P., we provide specialized care for children experiencing dehydration and other symptoms. We also offer NICU & PICU Ambulance Facility Services. Consult our expert today for the best pediatric emergency care.
For More Details:
Map: https://cutt.ly/BwCeflYo
Name: Apollo Hospital
Address: Singar Nagar, LDA Colony, Lucknow, Uttar Pradesh 226012
Phone: 08429021957
Opening Hours: 24X7
Get Covid Testing at Fit to Fly PCR TestNX Healthcare
A Fit-to-Fly PCR Test is a crucial service for travelers needing to meet the entry requirements of various countries or airlines. This test involves a polymerase chain reaction (PCR) test for COVID-19, which is considered the gold standard for detecting active infections. At our travel clinic in Leeds, we offer fast and reliable Fit to Fly PCR testing, providing you with an official certificate verifying your negative COVID-19 status. Our process is designed for convenience and accuracy, with quick turnaround times to ensure you receive your results and certificate in time for your departure. Trust our professional and experienced medical team to help you travel safely and compliantly, giving you peace of mind for your journey.
DECODING THE RISKS - ALCOHOL, TOBACCO & DRUGS.pdfDr Rachana Gujar
Introduction: Substance use education is crucial due to its prevalence and societal impact.
Alcohol Use: Immediate and long-term risks include impaired judgment, health issues, and social consequences.
Tobacco Use: Immediate effects include increased heart rate, while long-term risks encompass cancer and heart disease.
Drug Use: Risks vary depending on the drug type, including health and psychological implications.
Prevention Strategies: Education, healthy coping mechanisms, community support, and policies are vital in preventing substance use.
Harm Reduction Strategies: Safe use practices, medication-assisted treatment, and naloxone availability aim to reduce harm.
Seeking Help for Addiction: Recognizing signs, available treatments, support systems, and resources are essential for recovery.
Personal Stories: Real stories of recovery emphasize hope and resilience.
Interactive Q&A: Engage the audience and encourage discussion.
Conclusion: Recap key points and emphasize the importance of awareness, prevention, and seeking help.
Resources: Provide contact information and links for further support.
Gemma Wean- Nutritional solution for Artemiasmuskaan0008
GEMMA Wean is a high end larval co-feeding and weaning diet aimed at Artemia optimisation and is fortified with a high level of proteins and phospholipids. GEMMA Wean provides the early weaned juveniles with dedicated fish nutrition and is an ideal follow on from GEMMA Micro or Artemia.
GEMMA Wean has an optimised nutritional balance and physical quality so that it flows more freely and spreads readily on the water surface. The balance of phospholipid classes to- gether with the production technology based on a low temperature extrusion process improve the physical aspect of the pellets while still retaining the high phospholipid content.
GEMMA Wean is available in 0.1mm, 0.2mm and 0.3mm. There is also a 0.5mm micro-pellet, GEMMA Wean Diamond, which covers the early nursery stage from post-weaning to pre-growing.
About this webinar: This talk will introduce what cancer rehabilitation is, where it fits into the cancer trajectory, and who can benefit from it. In addition, the current landscape of cancer rehabilitation in Canada will be discussed and the need for advocacy to increase access to this essential component of cancer care.
Hypertension and it's role of physiotherapy in it.Vishal kr Thakur
This particular slides consist of- what is hypertension,what are it's causes and it's effect on body, risk factors, symptoms,complications, diagnosis and role of physiotherapy in it.
This slide is very helpful for physiotherapy students and also for other medical and healthcare students.
Here is summary of hypertension -
Hypertension, also known as high blood pressure, is a serious medical condition that occurs when blood pressure in the body's arteries is consistently too high. Blood pressure is the force of blood pushing against the walls of blood vessels as the heart pumps it. Hypertension can increase the risk of heart disease, brain disease, kidney disease, and premature death.
Hypertension and it's role of physiotherapy in it.
THE PATIENT WITH DECREASED VISION Classification and Management by Iddi.pptx
1. THE PATIENT WITH DECREASED
VISION: Classification and
Management
PRESENTER: Dr. Iddi Ndyabawe
MODULATOR: Dr. Atukunda Immaculate
Date: Tuesday 08/02/2022
Department of Ophthalmology
MAKCHS
2. Outline
• Ocular Media Abnormality
• Retinopathy
• Acute Idiopathic Blind-Spot Enlargement, Acute
Zonal Occult Outer Retinopathy, and Multiple
Evanescent White Dot Syndrome
• Cone Dystrophy
• Autoimmune Retinopathies and Paraneoplastic
Retinopathies
• Optic Neuropathy
• Visual Field Patterns in Optic Neuropathy
• Causes of Optic Neuropathy
• Optic Atrophy
• Chiasmal Lesions
• Visual Field Loss Patterns
• Etiology of Chiasmal Disorders
• Retrochiasmal Lesions
• Optic Tract
• Lateral Geniculate Body
• Temporal Lobe
• Parietal Lobe
• Occipital Lobe
3. GOAL
What’s the initial goal in the assessment of reduced vision in any patient?
To localize the cause of vision loss to a specific part of the visual pathway.
4. Ocular media abnormality
• What’s the main distinctive clinical ocular feature of irregularities or
opacities of the ocular media?
• They tend to reduce visual acuity, but they do not affect pupils, color vision,
or appearance of the posterior pole.
• List some examples:
• -corneal disease: DES, EBMD
• -Lenticular abnormalities
6. .
• When do we get RAPD in maculopathies?
• When there is extensive retinal
abnormality
• What’s the major difference between
maculopathy and optic nerve disease as
related to colour vision and visual acuity?
• Maculopathy causes parallel losses in color
discrimination and VA
• Optic nerve disease causes a greater loss in
color vision than in VA
• What’s the classical VF defect in
maculopathy Vs optic nerve disease?
• Maculopathy VF defects are focal and central
• Optic nerve disease defects are larger, often
cecocentral, and part of a generalized
depression of visual field sensitivity
• Where do we commonly find
metamorphopsia?
• Maculopathy
• Which one produces visible fundus
abnormalities?
• Maculopathy
7. .
• Which investigation do we use for
detecting an abnormality in retinal
structure or function?
-Optical coherence tomography (OCT)
-autofluorescence imaging of the macula
-fluorescein angiography
-multifocal electroretinography (ERG)
• What are the differentials of
maculopathies?
-AIBSE
-AZOOR
-MEWDS
-cone dystrophy.
-cancer- associated retinopathy
-melanoma- associated retinopathy
• What retinal disorders can be
mistaken for optic neuropathies?
• -central serous chorioretinopathy
• -cystoid macular edema
8. AIBSE, AZOOR, MEWDS
• Traditionally what do we think when we see enlargement of the blind
spot on VF testing?
-edema or tilting of ONH
9. AIBSE
• What are the descriptive features of AIBSE?
• prominent visual symptom is a monocular scotoma, often temporal in location
and associated with photopsias.
• The main finding is an enlarged blind spot.
• The fundus may appear normal or show evidence of
• -ONH edema
• -peripapillary retinal lesions
• -choroiditis
• -changes in the retinal pigment epithelium
• -(RPE)
• -uveitis.
11. AZOOR
• more extensive retinal changes than AIBSE
• transient in nature.
• Prominent symptom: Photopsias (reflect disease of the outer retina.)
• Ix:
• Fundus examination shows characteristic small, deep retinal white spots in
the posterior retina that usually last for weeks and resolve spontaneously.
• Fluorescein angiography and indocyanine angiography are often abnormal.
• Multifocal ERG shows depression in the peripapillary region
• Full-field ERG response may show depressed a-waves or substantial intereye
asymmetry.
• Spectral- domain OCT may reveal attenuation of the outer layers.
13. CONE DYSTROPHY
• What are the features of cone dystrophy?
• Rare
• Vision loss: gradually progressive decrease in VA and colour vision
• Photophobia and hemeralopia (day blindness)
• What can we mistake for cone dystrophy?
• Bilateral optic neuropathy
• O/E:
• Early: fundus normal or slightly blunted foveal reflex and granular macular pigmentation
• Late: macular RPE becomes atrophic in central oval region, bull’s eye pattern of depigmentation
• Ix:
• Fluorescein angiography and fundus autofluorescence
• ffERG: markedly depressed cone response. Less prominently affected rod response
• mfERG: central depression
• OCT: thinning of outer macular layers, loss of ellipsoid zone and outer cavitation
15. AUTOIMMUNE RETINOPATHIES AND PARANEOPLASTIC RETINOPATHIES
• CANCER-ASSOCIATED RETINOPATHY:
• How does CAR present?
• Bilateral progressive vision loss
• Impaired colour vision
• Photopsias
• Nyctalopia
• Impaired dark adaptation
• Ring scotoma
• VF loss: peripheral and/or central
16. .
• What’s the most common cause of
CAR?
• Small-cell lung carcinoma
• What are ocular findings in CAR?
• Early: fundus can be normal. But ERG
shows markedly reduced amplitudes
• On progress: retinal arterioles becomes
attenuated, the RPE thins and mottles
and ONH atrophies. Vision loss is
severe.
• What tests do we do in CAR?
• Serum antiretinal antibody testing:
• Western blot
• Immunohistochemistry
• What’s the best characteristized
antibody?
• Recoverin
• Rx:
• Corticosteroids
• Plasmapharesis
• IV immunoglobulin
• Prognosis: poor
19. MELANOMA-ASSOCIATED RETINOPATHY (MAR)
• Synopsis: rare syndrome that involves primarily rod bipolar cells
• What are the symptoms of MAR?
• Photopsia
• Nyctalopia
• Bilateral peripheral visual field loss
• What is classical about these symptoms?
• They occur after previously diagnosed melanoma
20. .
• What tests are normal in MAR?
• VA
• Color vision
• Central VF
• Fundus
• mfERG: because mfERG measures photopic responses, yet MAR affects rod
function
• What tests are abnormal in MRG?
• ffERG: rod dysfunction. Sometimes fundus exam shows RPE irregularity, retinal
arteriolar attenuation or ONH pallor.
• No Rx yet: but some success with IV Ig
21. NON PARANEOPLASTIC AUTOIMMUNE RETINOPATHY (NpAIR)
• Associated with autoimmune disease in about 50% of patients
• How does NpAIR present?
• Decreased visual acuity
• Peripheral visual field loss
• Positive visual phenomenon
• Nyctalopia
• Ix:
• ERG: cone-system dysfunction; macular or generalized
• NpAIR associated antibody targets.
• When can a clinician diagnose NpAIR?
• After comprehensive systemic investigation to exclude occult malignancy
22. OPTIC NEUROPATHY
• What is the main typical clinical presentation of a patient with optic
neuropathy?
• VA loss
• VF loss
• Dyschromatopsia
• RAPD
• ONH: normal or acutely swollen; optic atrophy happens 4-6 weeks later
23. VF patterns in Optic Neuropathy
• 3 major groups of retinal ganglion cell nerve fibres. VF loss related to these.
• Papillomacular fibers: cecocentral scotoma, paracentral scotoma and central
scotoma
• Arcuate fibers: arcuate scotoma, altitudinal defect, nasal step defect
• Nasal radiating fibers: temporal wedge defect
26. Causes of Optic Neuropathy
• How are optic neuropathies classified?
• Anterior: with ONH edema
• Posterior: with a normal appearing ONH at onset
• What clinical characteristics are helpful in determining the cause of optic
neuropathy?
• patient’s age
• mode of onset
• Laterality
• presence of pain
• color vision
• type of visual field defects
• optic nerve appearance
• results of orbital magnetic resonance imaging (MRI)
28. Papilledema
• How do you define papilledema?
• Papilledema refers to ONH edema resulting
from increased intracranial pressure (ICP).
• On ophthalmoscopy, papilledema is
indistinguishable from other causes of ONH
edema.
• What are the chief complaints in a pt with
papilledema?
• Headache
• Nausea
• Vomiting
• Transient visual obscurations—episodes of
unilateral or bilateral vision loss lasting
seconds.
How do we call those episodes?
• “grayouts,” “whiteouts,” or “blackouts” of
vision, often occurring with orthostatic
changes.
• In early papilledema which findings are
normal?
-optic nerve function, including visual acuity
and color vision
-Pupillary responses are also normal;
• Which test is abnormal in early
papilledema?
• visual fields demonstrate only
enlargement of the blind spot
29. .
• What are the classical findings in acute/early papilledema?
• Hyperemia of the ONH
• Dilation of existing ONH surface capillary net
• Telangiectasia of surface and radial peripapillary vessels
• Edematous peripapillary RNFL is grayish white and opalescent, with
feathered, striated margins that obscure the retinal vessels
• others: ONH and peripapillary cotton-wool spots, exudates and hemorrhages
• Where does early papilledema begin?
• At the superior and inferior poles of the ONH
31. .
• As papilledema worsens, what do we see regarding the ONH?
• Whole ONH is encompassed
• C-shaped area of ONH edema with the opening along the temporal rim.
• Blurring of major vessels off the ONH
• What are the late findings in papilledema?
• Absence of the physiologic cup and obscuration of vessels on the ONH itself
• What reflects increased ICP?
• Absence of spontaneous venous pulsations
32. .
• What are the differentials of papilledema?.... Pseudopapilledema
• Optic drusen
• Hyaloid remnants and glial tissue on ONH surface
• Congenital ‘fullness’ of the ONH
• ONH ‘fullness’ associated with hyperopia
• Viteropapillary traction
• Myelination in the RNFL
34. .
• What are some of the causes of papilledema?
• an intracranial mass
• hydrocephalus
• meningeal processes, such as an infection of the central nervous system (CNS) or infiltration
by a granulomatous or neoplastic process
• increased venous pressure from cerebral venous thrombosis or dural fistula
• IIH
What investigations do we do in papilledema?
Urgent brain imaging: MRI and MRV of orbits and brain with contrast.
Why do the above Ix?
To r/o SOL and cerebral venous thrombosis.
What if brain imaging is normal? What do we do?
Do LP to evaluate CSF opening pressure and composition
36. Chronic Papilledema
• When do call it chronic?
• After months to years
• How does the ONH appear here?
• No longer hyperemic
• Looks pale due to chronic axonal loss
• What additional features do we see here?
• Gliosis of the peripapillary RNFL: grayish, vascular sheathing
• Optocilliary shunt vessels (retinochoroidal collaterals): preexisting channels on the
ONH surface. Enlarge over time.
• Refractile bodies of the ONH: from chronic lipid-rich exudation. Remain on surface,
esp at OD margin
38. .
• How do refractile bodies of the ONH differ from drusen?
• Refractile bodies of ONH are smaller and noncalcified
• What VF defects do we see in chronic papilledema?
• Nasal field loss
• Arcuate scotoma
• Generalised peripheral depression
• When do we find central visual field involvement?
• Late
39. Idiopathic Intracranial Hypertension
• A.K.A: pseudotumor cerebri
• How do these patients present?
• Features of elevated ICP
• What are they?
• Headache
• Neck and back pain
• Pulsatile tinnitus (Pulse synchronous bruit)
• Nausea
40. .
• What do we see on ocular exam in IIH?
• Papilledema
• CN 6 palsy
• Normal VA
• Enlarged blind spot on perimetry testing
• Optic nerve function
• What’s the epidemiology of IIH
• Incidence peaks in 3rd decade of life
• 90% are women
• 90% are obese
• Rare in prepubertal children, men and lean
adults
• What are the risk factors of IIH?
• Vitamin A > 100,000 IU/day
• Tetracycline
• Minocycline
• Doxycycline
• Retinoic acid
• Lithium
• Use of or withdrawal of use of corticosteroids
• Sleep apnea
41. .
• What are the DDx of IIH?
• Cerebral venous disorders: Cerebral venous thrombosis; from trauma,
childbirth, hypercoagulable state, compression, ear or CNS infection
• Systemic or localized extracranial venous obstruction: after radical neck
dissection
• Dural arteriovenous malformation
• Systemic vasculitis
• What’s the mech of causing elevated ICP in above cases?
• Decreased venous outflow
42. .
• What do we do to r/o above DDx?
• MRI: r/o mass, hydrocephalus, meningeal lesion
• MRV: look for venous sinus occlusion
• What are the characteristic MRI findings of IIH?
• Flattening of globes
• Enlarged optic nerve sheaths
• Partially empty sella
• Narrowing of distal transverse venous sinus
What can we do to confirm elevated ICP and to r/o infectious inflammatory process?
LP
45. What’s the role of the ophthalmologist in
management of IIH?
• Regular check up: VA, Color vision, quantitative perimetry to document level of optic
nerve function
• Photographs of ONH
• Repeat OCT to document improvement of papilledema
• Why can’t we use OCT alone for follow-up of papilledema?
• Secondary optic atrophy from untreated papilledema can lead to apparent
improvement of the RNFL thickness on OCT.
• How do we handle the above controversy?
• GCC of macula shows thinning in decreased RNFL due to optic atrophy
• GCC of macula is normal in decreased RNFL due to resolution of papilledema
46. Treatment of IIH
On what factors does IIH treatment depend?
-symptomatology
-vision status
Is the disease self-limiting?
Yes
When don’t we need medical therapy in IIH?
If headache is mild or absent and optic nerve function is normal
What happens if we don’t treat the papilledema in IIH?
Severe vision loss in 5-10% of patients with IIH
47. .
• Which patients have poor visual prognosis?
• African American
• Male
• Morbid obesity
• Severe papilledema
• Anemia
• Fulminant course
• Abnormal VF testing at presentation
• RAPD
48. .
• Weight loss for obese patients. Refer
to nutritionist
• What’s the first DOC for IIH requiring
medical rx?
• Acetazolamide 1-4g/day. (IIHTT 2014)
• What other drug can we use esp in
pt with chronic headache?
• Topiramate
• What can we use if pt can’t tolerate all
both above drugs?
• Furosemide
• Why should we avoid corticosteroids?
• Recurrence common with steroid taper and
weight gain can worsen IIH
• When can we use corticosteroids and how?
• In severe papilledema and vision loss
(fulminant IIH) … Short course of high-dose
IV corticosteroids
49. .
• When do we consider surgical therapy in IIH?
• In cases of progressive vision loss despite maximally tolerated medical therapy
• Severe vision loss and papilledema
• What are the surgical options?
• ONSF
• CSF diversion procedure: lumboperitoneal or ventriculoperitoneal shunt
51. ONSF
• In which patients of IIH do we prefer to do
ONSF?
• Those with substantial loss of vision without
prominent headache
• Why?
• It directly protects the optic nerve and has
lower morbidity than associated with
shunting
• What are the complications of ONSF?
• 1-2% risk of vision loss from optic nerve
injury, CRAO, CRVO
• Does ONSF reliably treat headache?
• No
• Why?
• Because it doesn’t significantly lower
ICP
• Why are repeat ONSF procedures
technically more difficult?
• Because of scarring
52. .
• What is the advantage of shunting
over ONSF?
• In shunting, there is no risk of optic
nerve damage
• What’s the disadvantage of a shunt?
• Shunt may become occluded,
infected or altered in position
• Why is it that many patients of IIH
have chronic headaches despite
effective treatment of increased ICP?
• Because these headaches are not
directly related to increased ICP
• What’s special about ICP in children?
• No gender predilection
• Non-obese children affected more
• CSF opening pressure among children
is higher.>28cmH20
• Rx same as adult IIH
53. OPTIC NEURITIS
• What is optic neuritis?
• any cause of optic nerve inflammation
• How is it classified?
• Isolated Vs part of demyelinating disorder..
• Retrobulbar Vs Papillitis
• What is retrobulbar optic neuritis?
• When it affects the posterior portion of the
optic nerve
• the ONH appears normal at the time of
vision loss.
• What is papillitis?
• when the inflammation involves the
anterior portion of the nerve
• the ONH appears edematous: hyperemic
and diffuse
• Which kind of papillitis is most manifest in
children?
• Postviral optic neuritis and papillitis
• Bilateral vision loss
57. Isolated optic neuritis
• In which age group do we see it?
• Young: mean age 32yrs
• Female
• How does it present?
• Subacute monocular vision loss over
several days
• Which form is prevalent here?
• Retrobulbar form in 65% of cases
• What are the ocular exam
features in isolated optic neuritis?
• RAPD unless bilateral and
symmetric
• Pertimetry: central depression
• Dyschromatopsia esp red-green
• Sequeale: improves in 1 month
62. .
• What atypical features of optic neuritis prompt further evaluation?
• Older age
• Lack of pain
• Severe vision loss
• Significant swelling of the ONH with peripapillary hemorrhages or exudates
• Inflammatory ocular features: uveitis, phlebitis, choroiditis, pars planitis
• Pre-existing systemic dx: cancer, vasculitis, ISS
• Retinal changes
• Bilateral vision loss
• Involvement of other CN
• Steroid-responsive optic neuropathy
• Lack of any vision recovery by 1 month
63. Which tests do we do in atypical cases of optic
neuritis?
• serum and CSF RPR and FTA-ABS
testing for syphilis
• serum testing for Bartonella infection
• serum testing for Lyme disease (if
endemic)
• chest x-ray or (CT)
-serum ACE testing for sarcoidosis
• ESR determination, ANA, and anti- DNA
antibody testing for SLE or vasculitis
• ANCA for Wegener granulomatosis
• serum or CSF aquaporin-4
immunoglobulin G (AQP4-IgG) antibody
testing and spinal MRI for NMOSD
• genetic testing for LHON
• brain and orbit MRI with gadolinium
contrast for compressive, infiltrative
disorders
• LP with cytology for a meningeal process
64. What’s the natural history of optic neuritis?
• Optic neuritis recurs in affected or fellow
eye in 35% of cases overall
• 48% convert to MS
• 92% recover VA better than 20/40
• Pt remains aware of visual deficits in
affected eye after recovery.
• MRI should be performed in every case of
Optic Neuritis. True or False?
• What’s the main role of MRI?
• To assess the future risk of MS
• Which patients have a lower risk of future
MS?
• Male
• ONH swelling
• Atypical features of optic neuritis (no pain,
NPL, peripapillary hemorrhages, retinal
exudates)
65. Treatment of Optic neuritis
• ONTT showed no long term benefit of corticosteroids
• But use of intravenous methylprednisolone, 250 mg every 6 hours for 3 days, followed by oral
prednisone, 1 mg/kg/day for 11 days (with a quick taper of 4 days), sped recovery by 1–2 weeks.
• What happens when a patient receives prednisolone alone?
• No improvement in vision.
• Recurrence twice as that of other groups
• So is oral prednisolone recommended for isolated optic neuritis?
• No it’s not
• In which patients did they find a role for high-dose IV corticosteroids? What role is this anyway?
• Pts with MRI scans showing 2 or more white matter lesions.
• Where we need a rapid return of vision: monocular patients or patients with an occupational need
• Role: reduces rate of development of clinically definite MS after the initial optic neuritis
66. .
• What’s the rationale of immunomodulatory therapy in Optic neuritis?
• Delays conversion of Optic neuritis to MS
• Reduces morbidity in relapsing-remitting form of MS
68. Chronic relapsing inflammatory optic neuropathy
(CRION)
• What kind of optic neuritis is CRION?
• Isolated optic neuritis that is steroid responsive and steroid dependent
• Why call it chronic?
• Occurs over months to years
• How do we treat it?
• Long term corticosteroid and/or immunosuppressive therapy
• Is CRION associated with MS?
• No
• When we suspect CRION, what should we rule out?
Other inflammatory disorders like sarcoidosis
69. Neuromyelitis Optica (NMO)
• What’s its other name?
• Devic disease
• What are the main characteristics of NMO?
• Optic neuritis and acute myelitis
• More rapid
• Unilateral ON
• F>M (9:1)
• Mild disc edema or normal
• No pain in hx
• What then is NMOSD?
• First attack or limited form of optic neuritis or transverse myelitis
• Typical clinical NMO associated with cerebral, diencephalic or brainstem lesions
71. .
• What’s the interval of occurrence of
Myelitis and Optic neuritis?
• Within weeks to months. May be
separated by several years
• Compare the neurologic prognoses in
NMO vs MS…
• Those in NMO are poorer than in MS
• In which scenarios of optic neuritis
do we have to do AQP4-IgG test?
• Profound vision loss
• Irreversible vision loss
• Bilateral optic neuritis
• Recurrent optic neuritis
• Extensive enhancement of the optic
nerve on MRI
72. .
• What other tests help to confirm NMO?
• CSF Pleocytosis (>50WBC, PMN)
• Oligoclonal bands uncommon
75. .
• What’s the mainstay of treatment during the acute periods of NMO?
• High-dose IV corticosteroids
• What do we do for poorly responsive NMO?
• plasmapheresis or intravenous immunoglobulin,plus high-dose intravenous
methylprednisolone
84. Neuroretinitis
• Define Neuroretinitis?
• an inflammatory disorder characterized
by acute loss of vision associated with
ONH edema and a star pattern of
exudates in the macula.
• What’s the pathology in this condition?
• Diffuse ONH edema spreads thru the
plexiform layer along the papillomacular
bundle and around fovea
• As fluid resorbs, lipid precipitates in
radial pattern in Henle layer
• When does the macular star appear in
Neuroretinitis?
• At initial presentation or several days
later
• What is crucial for correct diagnosis of
neuroretinitis?
• Recognizing fluids or lipid exudates in
the papillomacular bundle
86. .
• What’s the etiology of neuroretinitis?
• Infectious or post-viral autoimmune
process
• Elevated IgM titres for Bartonella
quintana or Bartonella henselae
• Which other disease is related to the
above?
• Cat-scratch disease
• What other potential infectious and
inflammatory causes are linked to
neuroretinits?
• Lyme disease
• Sarcoidosis
• Syphilis
• Toxoplasmosis
• Tuberculosis
• Viruses
• Is there any evidence for role of
corticosteroids and antibiotics in this
disease?
• No
87. Optic perineuritis
• What is optic perineuritis?
• Inflammation of the optic nerve sheath
• What are the similarities between optic
neuritis and optic perineuritis?
• Acute, painful vision loss
• Female predilection
• What are the distinguishing features of
optic perineurits?
• Patients generally older
• Vision loss is often milder: central vision
relatively spared
• Progresses over several weeks
• Pain persists until treatment is initiated
• Orbital MRI shows enhancement of optic
nerve (dural) sheath rather than optic
nerve itself. Pain diff btwn OP and ONSM.
• Optic perineuritis is not associated with
MS
• Rx:
• Corticosteroids
88. ISCHEMIC OPTIC NEUROPATHY
• How is ION classified?
• AION and PION
• Anterior Ischemic Optic
Neuropathy (AION)
• What’s its prevalence?
• Most common acute optic
neuropathy in patients older
than 50 years
• What are the symptoms?
• Painless monocular vision loss
that develops over hours to days
• What are the exam findings?
• VA relatively preserved
• VF loss always occurs: altitudinal
defects, arcuate defects
• RAPD unless its bilateral
• Pathognomic: ONH edema at
onset, may precede vision loss
89. .
• How do we classify AION?
• AAION: associated with vasculitis
• NAION
• What’s the most important step in evaluating AION?
• To distinguish above subtypes
91. ARTERITIC AION (AAION)
• What’s its prevalence?
• Less common AION. 5%
• Occurs in >50yrs. Mean age 70yrs
• What causes AAION?
• Inflammatory and thrombotic occlusion of the short
posterior ciliary arteries
• What features of GCA are present in AAION?
• Headache
• Scalp tenderness
• Jaw claudication
• Malaise
• Anorexia
• Weight loss
• Fever
• What feature is very suggestive of GCA?
• Transient vision loss or transient diplopia preceding AION
• What percentage of patients with vision loss from GCA don’t
have systemic symptoms?
• 25%
• How do we call that?
• Occult-GCA
92. .
• Which tests help confirm that we have GCA?
• ESR
• C-reactive protein
• What are the funduscopic features suggestive of AAION>NAION?
• chalky-white ONH edema (in NAION, the ONH is often hyperemic)
• cotton-wool spots away from the ONH, which indicate concurrent retinal
ischemia (cotton- wool spots on or adjacent to the ONH can be present in
NAION)
• delayed choroidal filling on fluorescein angiographic studies (normally, the
choroid fills completely within 3–5 seconds, before the retinal arteries do)
• normal or large cup in the fellow eye (in NAION, a small cup–disc ratio is
common)
95. .
• What should we do incase we
suspect AAION due to GCA?
• Immediate initiation of high-dose
corticosteroids
Intravenous methylprednisolone (1 g/day for the first 3–5 days) is usually recommended.
Thereafter, oral prednisone (1 mg/kg/day) may be used (up to 100 mg/day, tapered slowly
over 12 months or more, depending on response).
• Adjunctive aspirin
• Temporal artery biopsy to confirm the
diagnosis
• What’s the goal of AAION therapy?
• To prevent contralateral vision loss
• To avoid systemic vascular
complications
• If we don’t treat AAION, what
percentage of cases will involve
the fellow eye?
• 95%
• Does the patient’s vision fully
recover?
• No
• Why should we taper the
corticosteroids slowly?
• Risk of recurrent or contralateral
optic nerve involvement during
corticosteroid withdrawal
96. NONARTERITIC AION (NAION)
• What’s the prevalence of NAION?
• Most common. 95% of AION
• In younger pts. Mean age 60yrs
• Which eyes are prone to NAION?
• Those with structural ‘crowding’ of the ONH hence compromising the ONH microcirculation
• What is the local compartment syndrome theory?
• The area of infarction is located within the scleral canal alone
• What two forms of NAION?
• Static
• Progressive
• Is NAION associated with any systemic symptoms?
• No
97. .
• What are the vascular risk factors of NAION?
• DM
• HTN
• Smoking
• Hypercholesterolemia
98. Ocular features of NAION
• NAION vs AION, which one has less severe vision loss?
• NAION (>20/200 in >60% of cases)
• VA and colour may be normal
• RAPD is present
What’s the most common VF defect?
Altitudinal defect
Describe the ONH edema in NAION.
Diffuse or segmental. Initially hyperemic.
Describe the ONH in the contralateral eye.
Typically small in diameter. A small or absent physiologic cup (“disk at risk”)
When does the ONH become atrophic?
Within 6-8 weeks of NAION onset
100. FOSTER KENNEDY SYNDROME
• What is pseudo-Foster Kennedy syndrome?
• Occurrence of NAION in the second eye in which:
-the previously affected ONH is atrophic
-currently involved ONH is edematous
• What is True Foster-Kennedy syndrome?
• Secondary to intracranial mass
• 1 ONH is atrophic due to chronic compression by the mass
• The other ONH is edematous because of elevated ICP
101. .
• What are the risk factors of
NAION?
• structural crowding of the ONH
(“disc at risk”)
• diabetes mellitus (particularly in
young patients)
• systemic hypertension
• hyperlipidemia
• sleep apnea
• What do we know about amiodarone and
NAION?
• Amiodarone may trigger an anterior optic
neuropathy with ONH edema similar to
NAION
• What can we do in unclear cases to
distinguish NAION from optic neuritis?
• Contrast-enhanced MRI of the orbits (with
fat suppression)
• What do we see?
• Affected optic nerve is normal in NAION but
enhanced in optic neuritis
103. .
• Is there any treatment for NAION?
• No
• How do we know?
• IONDT: Ischemic Optic Neuropathy Decompression Trial
• ONSF used earlier but no benefit
• Is there any prophylaxis for the fellow eye?
• No
• So how do we prevent NAION?
• Since 60% of NAION patients have systemic vascular risk factors, look for and treat
these
• Why should we refer NAION patients for risk factor modification and management?
• Increased risk of cerebral ischemic stroke
104. POSTERIOR ISCHEMIC OPTIC NEUROPATHY (PION)
• Is it common?
• No it’s rare. Dx of exclusion
• What are the ocular features of PION?
• Severe vision loss
• RAPD
• Initially normal-appearing ONHs
• What causes PION?
• Acute ischemic damage to the retrobulbar portion of the optic nerve
• But do we really understand the causes of PION?
• No. multifactorial
105. .
• What are the 3 scenarios of occurrence of PION?
(1) perioperative (most commonly in spine, cardiac, and head or neck
procedures)
(2) arteritic (especially from GCA)
(3) nonarteritic (with risk factors and a clinical course similar to those of
NAION).
106. PERIOPERATIVE ISCHEMIC OPTIC NEUROPATHY
• What are the 2 most common procedures associated with ischemic optic neuropathies?
• Coronary artery bypass grafting
• Prolonged spinal-fusion surgery
• What other conditions can lead to this condition?
• After severe blood loss, intraoperative hypotension, renal dialysis, severe anemia.
• Why the concern yet these are <0.5% cases?
• Medical legal issues
• Which surgeries are more linked with AION?
• Cardiac surgery
• What surgeries are more linked with PION?
• Spine surgery
107. DIABETIC PAPILLOPATHY
• Is diabetic papillopathy related to NAION or AION?
• NAION
• What are the symptoms here?
• No symptoms or nonspecific symptoms: blurred
vision, or ‘distortion’ without pain
• What are signs?
• Evidence of optic nerve dysfunction (VA, VF, RAPD) is
variable
• Optic nerve reveals hyperemic edema, marked
dilation of ONH surface vessels similar to NVD
• How do we distinguish NVD from diabetic
papillopathy?
• The vessels in NVD proliferate into the vitreous cavity
and leak fluorescein in angiographic studies
• Is diabetic retinopathy universal among patients
with diabetic papillopathy?
• No
• 63-80%
• What’s the pathophysiology?
• Unclear . Suspected to be mild, reversible ischemia
• Can we distinguish diabetic papillopathy from
AION?
• Controversial. They represent a spectrum
• Is there treatment for diabetic papillopathy?
• no
110. Papillophlebitis
• What does it represent?
• Represents a subset of CRVO
• What are the symptoms of papillophlebitis?
• Vague blurring of vision
• Transient visual obscurations
• What are the ocular exam findings in papillophlebitis?
• VA is normal
• Pupils and color vision are normal
• VF shows blind spot enlargement
• Fundus: marked retinal venous engorgement plus hyperemic ONH edema; retinal hemorrhages till equatorial
region
• Fluorescein angiography: retinal venous staining and leakage assoc with circulatory slowing
• How does the fluorescein angio of papillophlebitis differ from that of CRVO?
• no regions of capillary occlusion in papillophlebitis unlike in CRVO
111. .
• What else do we r/o when we have papillophlebitis?
• Hypercoagulable disorders
• How long does it take for papillophlebitis to resolve?
• 6-12 months
113. Compressive or infiltrative optic neuropathies
• How do patients with intraorbital or intracanalicular compressive lesions
present?
• Progressive vision loss
• RAPD
• Monocular VF loss
• Signs of orbital disease: eyelid edema, eyelid retraction, lid lag, proptosis
• ONH may be normal or atrophic. ONH edema seen in anterior orbital lesions
• Optociliary shunt vessels or choroidal folds
116. .
• Which lesions most commonly
produce optic neuropathy?
Optic nerve sheath meningioma
and optic nerve glioma
• What infiltrative processes an
involve the optic nerve?
• Inflammatory, infectious or
neoplastic
• Where do we usually find
infiltration of the optic nerve?
• Retrobulbar process
• If we have anterior involvement,
how does it present?
• ONH edema
• When should we consider ancillary
testing for an infiltrative lesion?
• When ONH edema or vision loss
persist atypically
• When prelaminar infiltrate is visible
• How does prelaminar infiltrate
appear?
• More opaque
• Grayish or yellowish discoloration
118. .
• What do we do when we suspect an orbital compressive lesion?
• Neuroimaging
• What is good for soft tissue abnormalities, particularly for diff
meningioma vs glioma?
• MRI
• What is best for evaluation of calcification and bony abnormalities?
• CT scan
119. Optic nerve sheath meningioma and intracranial
meningioma
• Where does an optic nerve sheath meningioma arise from?
• From proliferations of the meningioepithelial cells lining the sheath of the
intraorbital or intracanalicular optic nerve
• What explains the genesis of intracranial meningioma involving the optic
nerve?
• Compression from the involved sphenoid wing or tuberculum sella
• Most meningiomas involving orbit represent extensions from intracranial sites
• Are most ONSM unilateral or bilateral?
• Unilateral (90%)
120. .
• What’s the prevalence of ONSM?
• Uncommon
• 1/3 of optic nerve tumors; 2nd only to optic nerve glioma
• Detected in middle aged women
• Rare in children
• What’s the diagnostic triad of ONSMs?
1. painless, slowly progressive monocular vision loss
2. optic atrophy
3. optociliary shunt vessels
121. .
• What are optociliary shunt vessels?
• preexisting ONH channels that dilate in
response to chronic obstruction of outflow
through the central retinal vein.
• What’s their role?
• These vessels shunt retinal venous outflow
to the choroidal circulation.
• In how many pts of ONSM do we find
them?
• 50%
• Which other conditions have them?
• sphenoid wing meningioma
• optic nerve glioma
• CRVO
• chronic papilledema
• What other notable ocular exam findings
for ONSM?
• RAPD
• Optic nerve related VF defect
• ONH edema may be present, especially if
the tumor extend anteriorly.
• How do we confirm the diagnosis?
• Neuroimaging
126. .
• What’s the treatment of choice for
ONSM?
• Fractionated radiation therapy
• How efficient is it?
• produces stability or vision
improvement in up to 95% of
patients.
• What are the common late radiation
complications?
• radiation retinopathy and pituitary
dysfunction
• Why is surgery (ie, biopsy or
excision) typically ill- advised for
ONSM?
• because of the considerable
potential for significant vision loss.
• When do we do surgical debulking?
• if the tumor extends intracranially
• when severe ipsilateral vision loss is
present
127. .
• Regarding a residual tumor, when do we do radiation therapy?
• following surgery on the residual tumor.
• When do we do mere Observation?
• if there is no change in visual function or tumor size
• Why should children with ONSM be monitored more frequently?
• ONSMs in children may be more aggressive, with more rapid vision
loss and more frequent recurrence after therapy.
130. Optic pathway glioma
• What’s their other name?
• pilocytic astrocytomas
• What’s their prevalence?
• uncommon (1% of intracranial tumors)
• most common primary tumor of the optic nerve.
• Which structures do they involve?
• They may involve the optic nerve, the chiasm, or both.
131. .
• When are OPGs mostly detected?
• In first decade of life and 90% by the second; but can occur at any age. No
definite sex predilection.
• What are the clinical features?
• proptosis (94%)
• vision loss (87.5%)
• ONH pallor (59%)
• ONH edema (35%)
• strabismus (27%).
• asymptomatic isolated optic atrophy; infrequent
• RAPD: unilateral or asymmetrical cases
• typical optic nerve–related visual field defect
• Optociliary shunt vessels: less common than in ONSM
132. .
• How is the diagnosis confirmed?
• neuroradiologic findings
• What’s the adage of NF-1 and OPG prevalences?
• In patients with neurofibromatosis 1 (NF1), the prevalence of OPG is
7.8%–21%.
• In contrast, in patients with OPG, the prevalence of NF1 is 10%–70%.
• Why is it that biopsy of OPGs is generally not required?
• advent of high- resolution neuroimaging has improved diagnostic accuracy
• biopsy of the optic nerve substance may cause additional vision loss
133. .
• What so we get with OPGs involving the chiasm?
• bitemporal or bilateral optic nerve–related visual field defects.
• see-saw nystagmus or a monocular shimmering nystagmoid oscillation
(pseudo–spasmus nutans).
• What do large tumors cause?
• obstructive hydrocephalus
• How do we know the above is present?
• elevated ICP
• Headache
• Papilledema
• What happens if we have involvement of the hypothalamus?
• precocious puberty or diencephalic syndrome.
135. .
• Is there any universally accepted
treatment of OPGs?
• No
• In which patients is observation
indicated?
• for patients with relatively good vision
and stable radiographic appearance.
• What is offered as the initial treatment
for patients with severe vision loss at
presentation or evidence of
progression?
• Chemotherapy
• Why is radiotherapy controversial?
• because of inconclusive results and
potential complications, including
panhypopituitarism and cognitive
impairment.
• When is surgical excision indicated?
• in patients with severe vision loss
associated with disfiguring proptosis.
• Surgery has been suggested to prevent
advancement into the chiasm
• What do we do for Hydrocephalus?
• CSF shunting.
136. Malignant gliomas of the anterior visual pathway, or
malignant optic gliomas of adulthood (MOGAs)
• rare neoplasms that almost always occur in adulthood.
• mean age is 60s, no gender predilection.
• Vision loss is often very rapid.
• acute- onset periorbital pain
• DDx: optic neuritis or NAION.
How is the ONH in MOGAs?
• The ONH appears normal or pale at presentation in most cases, but ONH edema and retinal
obstruction can also occur.
• What if the tumor originates in the distal portion of the optic nerve or the optic chiasm?
• vision loss may be simultaneously bilateral and associated with a pale or normal- appearing ONH.
137. .
• What does an MRI scan show in
MOGAs?
• diffuse intrinsic enlargement and
enhancement of the affected optic
nerves, chiasm, and optic tracts, with
inhomogeneity due to cystic spaces
within the tumor.
• Histologically, how are MOGAs
classified?
• anaplastic astrocytomas
• glioblastoma multiforme.
• Is treatment always successful?
• treatment is rarely successful
• When does blindness develop
after onset of vision loss?
• 2–4 months.
• When does death from
hypothalamic and brainstem
involvement occurs?
• within 12 months.
138. Thyroid eye disease (TED)
• How does it usually present?
• progressive enlargement of extraocular
muscles or orbital fat hypertrophy.
• What signs?
• associated signs (eg, eyelid retraction and
lid lag)
• signs of orbital congestion (eg, eyelid and
conjunctival edema) in addition to
proptosis.
• Describe the vision loss associated with
TED.
• slowly progressive, insidious, and bilateral.
• .
• What does Dyschromatopsia indicate?
• may be an early sign of optic neuropathy.
• What do Visual field testing results show?
• central or diffuse depression
• When do we find an RAPD?
• when the optic neuropathy is asymmetric or
unilateral.
• How does the ONH appear in TED?
• The ONH is commonly normal but may be
mildly edematous. Optic atrophy may be
present in chronic cases
139. .
• How can we reduce compression on the optic nerve in the acute
phase?
• Use of systemic steroids.
• What other Rx strategies?
• In some cases, surgical decompression of the posterior orbit is done.
radiation therapy alone is controversial.
144. Infiltrative optic neuropathy
• What really happens here?
• Infiltration of the optic nerve by neoplastic or
inflammatory cells causing progressive, often
severe, vision loss.
• Describe how the ONH appears here.
• With retrobulbar infiltration, the ONH may
initially appear normal.
• In cases of ONH edema, the cellular infiltrate
creates a swollen appearance that may be
distinct from that of simple edema.
• What sign on fundus exam signals an
infiltrative process?
• The presence of vitreous cells or peripheral
vasculitis
• What are the most common causes of
infiltration?
• Leukemia
• Lymphoma
• Syphilis
• granulomatous inflammatory processes
such as fungal infections, sarcoidosis, or
tuberculosis.
• Are mets to the optic nerve common?
• No.
• Where do they usually come from?
• Usually occurring from breast or lung
carcinoma.
145. .
• How do Carcinomatous infiltration of
the meninges at the skull base present?
• vision loss
• dysfunction of multiple cranial nerves in
15%–40% of cases.
• How do we evaluate the cases of
suspected infiltrative optic neuropathy?
• MRI of the brain and orbits with fat
suppression
• Why would we use of gadolinium
contrast?
• to rule out compressive lesions and to
confirm pachymeningeal or meningeal
infiltration.
• What does the MRI scan show?
• diffuse thickening and enhancement of
the dura and the surrounding
subarachnoid space in affected regions,
including the optic nerve sheaths;
• when could these abnormalities not be
visible?
• in the early stages.
• What serologic testing is done?
• screening tests for the
myeloproliferative, inflammatory, and
infectious disorders.
146. .
• What do we see on the CSF analysis?
• malignant cells
• an elevated white blood cell count
• elevated protein levels consistent with a neoplastic, infectious, or
inflammatory cause.
• Why is repeat testing is often necessary or a LP?
• The sensitivity of a single lumbar puncture is low.
• Why is it essential to securing the correct diagnosis?
• to ensure timely treatment and to prevent life- threatening complications.
152. Hereditary optic neuropathies
• Leber hereditary optic neuropathy
(LHON)
• What’s the prevalence of LHON?
• typically affects boys and men aged
10–30 years
• What are the ocular exam findings
in LHON?
• acute, painless, sequential, and
severe vision loss (visual acuity,
<20/200)
• central or cecocentral visual field
impairment
• What is the classic fundus appearance
triad in LHON?
• 1. hyperemia and elevation of the ONH,
with thickening of the peripapillary
retina; although the ONH appears
swollen, it does not leak on fluorescein
angiography (“pseudoedema”)
• 2. peripapillary telangiectasia
• 3. tortuosity of the medium-sized
retinal arterioles
• What’s the classical presentation?
• One eye today, the other after weeks
153. .
• When does the unaffected eye become symptomatic?
• within weeks to months
• What is the pathogenesis of LHON?
• LHON results from a mitochondrial DNA mutation, most frequently at
the 11778 position, less commonly at the 3460 or 14484 locations.
• How do we confirm LHON?
• Results of blood testing for these mutations.
154. .
• How is the point mutation transmitted?
• by mitochondrial DNA, which is inherited
only from the mother; thus, only women
transmit the disease.
• What are the differential diagnosis of
LHON?
• includes all other causes of optic
neuropathies, particularly:
• optic neuritis
• compressive optic neuropathy
• infiltrative optic neuropathy.
• Which patients will need neuroimaging?
• For patients with a negative family history.
• Is there any effective treatment for LHON?
• No
• Why should patients with LHON avoid the
use of tobacco and curtail alcohol
consumption?
• Tobacco use or excessive alcohol intake
may stress mitochondrial function and thus
contribute to vision loss; therefore
158. Autosomal dominant optic atrophy
• What is the prevalence of ADOA?
• The most common hereditary optic neuropathy (estimated prevalence, 1:50,000)
• What is the inheritance pattern of ADOA?
• dominant inheritance
• On which chromosome do we find the ADOA gene (OPA1)?
• chromosome 3.
• Where is the OPA1 protein most abundant?
• in the retina.
• How does mutation of OPA1 lead retinal ganglion cell degeneration and optic atrophy?
• It encodes dynamin- related GTPase, which is anchored to mitochondrial membranes; thus,
mutations result in loss of mitochondrial membrane integrity and function
159. .
• When does ADOA usually presents?
• in the first decade of life
• How does ADOA present?
• At detection, visual acuity loss is usually
mild to moderate, ranging from 20/30
to 20/60, although acuity may decline
progressively.
• Most patients preserve a visual acuity
greater than 20/200.
• Color vision deficits, usually tritanopia
(blue- yellow). These patients may pass
evaluation with the Ishihara color
plates, which test red-green deficits.
• Which tests do we need for tritanopia?
• Hardy-Rand- Rittler plates or the
Farnsworth panel D-15 or D-100 test.
• What does the VF testing demonstrate?
• central or cecocentral loss.
• Do the VF defects respect the vertical
midline?
• No .
• How do the affected ONH appear?
• focal, wedge-shaped temporal optic
atrophy but diffuse pallor can occur.
160. .
• What do we base on to make the clinical diagnosis?
• examination findings and negative neuroimaging results
• When is genetic testing helpful?
• only when positive.
• How is the clinical course of ADOA?
• The clinical course is generally one of stability or very slow progression over
the patient’s lifetime (loss of approximately 1 Snellen line per decade).
• Is there any treatment for ADOA?
• No
162. Glaucoma
• When to patients with glaucoma note impaired
vision?
• When central vision is affected.
• Describe the VF loss in Primary open- angle
glaucoma.
• slowly progressive arcuate and peripheral visual
field loss, sparing fixation until late in the course.
• How is glaucoma distinguished from other optic
neuropathies?
• preserved color vision
• characteristic excavation of the optic cup
• Which other conditions have excavation of the
ONH?
• Compressive processes
• hereditary processes (LHON, ADOA)
• severe ischemic (AAION) processes.
• How do the above conditions differ from
glaucoma?
• In above cases, the nerve is pale in addition to being
cupped.
• ONH may demonstrate early and more prominent
pallor, with less severe excavation and notching
than in glaucoma
• These affect visual acuity and color vision, which are
late findings in glaucoma
• What VF loss is produced by Chiasmal compressive
lesions?
• temporal (hemianopic) rather than nasal visual field
loss.
165. Toxic or nutritional optic neuropathy
• What’s xtic of the vision loss in
this case?
• gradual, progressive, and painless
vision loss that is bilateral and
symmetric.
• What are the initial findings here?
• subtle depression of central vision
sensitivity on Amsler grid testing or
perimetry testing focused within
the central 10°.
• decrease in visual acuity and color
vision and a central scotoma.
• When does optic atrophy develop here?
• if the cause is not corrected.
• How does the ONH appear here?
• mild to moderate edema on presentation.
• What do we need to diagnose this?
• thorough patient history for possible
medication or other toxic exposure,
substance abuse, or dietary deficiency (as
may occur after bariatric surgery or
colectomy). Causation is usually
multifactorial.
167. .
What are the most commonly implicated agents in the development of toxic optic
neuropathies?
• Methanol
• ethylene glycol
• organic solvents
• lead (in children)
• tobacco (usually cigars)
• Ethambutol
• Linezolid
• Amiodarone
• Disulfiram
• Ciprofloxacin
• Antineoplastic drugs cisplatin and vincristine.
• interferon and anti–tumor necrosis factor alpha (anti-TNF-α) agents (eg, etanercept,
infliximab, and adalimumab).
168. .
• How does Amiodarone toxicity present?
• with bilateral vision loss and ONH
edema.
• How can it be differentiated from
NAION?
• by its subacute onset
• Bilaterality
• diffuse rather than altitudinal visual field
loss
• slow resolution of ONH edema over
months after discontinuance of the
medication.
• What are the differential diagnosis of toxic
or nutritional optic neuropathies?
• subtle maculopathies and hereditary,
compressive, demyelinating, and infiltrative
optic neuropathies.
• What do we do in questionable
cases?
• Fluorescein angiographic studies
• hematologic and serologic testing
• CSF analysis
• What is the goal of treatment?
• to reverse the inciting cause:
stopping medication or substance
abuse and resolving dietary
deficiencies.
• When do we have good prognosis
for vision recovery?
• If optic atrophy has not supervened
171. Traumatic optic neuropathy
• With which kind of trauma may the optic nerve be
damaged?
• by trauma to the head, orbit, or globe.
• What kinds do we have?
• Direct and indirect
• Which is more common?
• Indirect
• What causes Direct traumatic optic neuropathy
(TON)?
• by injury to the nerve itself
• laceration with bone fragments
• foreign bodies.
• Injuries may also cause compressive optic
neuropathy secondary to intraorbital or
intrasheath hemorrhage.
• What causes Indirect TON?
• relatively minor head injury. The trauma involves the
frontal or maxillary bone, and the transmitted forces
damage the optic nerve at the orbital apex. Avulsion
of the nerve may also occur.
• What’s the pathophysiology of indirect TON?
• shear forces on the nerve and possibly its vascular
supply in the optic canal.
• What kind of vision loss do we have here?
• typically immediate and often severe (24%–86% of
patients have no light perception at presentation).
172. .
• When do we get RAPD?
• In unilateral vision loss
• When does the ONH become
atrophic?
• After 4-8 weeks
• What Ix is done in TON?
• neuroimaging (head, orbit, and facial CT)
to assess the extent of injury and to detect
any associated intracranial and facial
injury, intraorbital fragments, or
hematoma.
• Is the therapy for indirect TON
controversial?
• Yes
• What was the major finding in the The
International Optic Nerve Trauma
Study?
• no clear benefit for treatment with
intravenous corticosteroids or optic canal
decompression, and no consensus exists
for their use, whether alone or in
combination.
173. .
• What is The Corticosteroid Randomization After Significant Head
Injury (CRASH) study?
• enrolled more than 10,000 patients with head injuries and compared
results from treatment with high-dose corticosteroids (2 g
methylprednisolone intravenous and then 0.4 g for 48 hours in a 20
mL/hour infusion) versus placebo within an 8-hour window after
trauma.
• The study was terminated early ; corticosteroid group had a
statistically significantly higher rate of mortality than the placebo
group.
• This finding raised safety concerns regarding the use of high-dose
corticosteroids in the treatment of TON, particularly in patients with
severe head trauma.
177. Optic disc drusen
• What is the other name for Optic disc drusen (ODD)?
• hyaline or colloid bodies
• What do they represent?
• refractile, often calcified nodules located within the optic nerve head
• What is the prevalence?
• ranges from 0.34% (clinical) to 2% (autopsy).
• equal frequency in males and females but rarely affect nonwhites.
• often bilateral (75%–86%) but can be asymmetric. They may be isolated or
dominantly inherited
178. .
• Is the pathophysiology of ODD clear?
• No
• What do most theories suggest?
• a process of impaired ganglion cell
axonal transport, probably related to
a small scleral canal and mechanical
obstruction.
• What do the Metabolic
abnormalities associated with
impaired transport cause?
• intra- axonal mitochondrial damage.
• What do the drusen represent?
• the product of deteriorating axons,
which extrude their contents into the
interstitial space.
• What are the associations with ODD?
• retinitis pigmentosa
• pseudoxanthoma elasticum.
179. .
• Do most patients with ODD have any
symptoms?
• No
• How do we explain some (8.6%) who may
have transient visual obscurations?
• Associated ONH swelling.
• Why should we evaluate for other causes of vision
loss when visual acuity declines or progressively
worsens?
• Because VA rarely declines in ODD
• How do the ONHs of patients with ODD
appear?
• elevated and small in diameter, with
indistinct or irregular margins and
associated anomalous vascular branching
patterns.
• the ONH does not show hyperemia or
dilation of the surface microvasculature
• Where does blurring of the ONH margin
arise from?
• From axoplasmic stasis in the axons deep
within the ONH; creating a yellowish, hazy
appearance that obscures the border
between ONH and retina but leaves the
view of the retinal vessels intact.
• How does RNFL edema appear in true
papilledema?
• whitish, fluffy, striated appearance.
180. .
• How do surface drusen look?
• may have a scalloped appearance.
• What ancillary testing may be
useful in differentiating ODD from
ONH edema (eg, papilledema)?
• B-scan ultrasonography
• Autofluorescence
• Fluorescein angiography
• Neuroimaging
• OCT
• What do we see in chronic
papilledema?
• refractile bodies occasionally develop
on the ONH surface, simulating ODD.
• Where do these lesions form?
• near the temporal margin of the ONH
rather than within its substance,
• How do they differ from ODD?
• smaller than ODD
• disappear with resolution of the
papilledema.
182. .
• In which conditions do we usually
find Astrocytic hamartomas of the
retina?
• in tuberous sclerosis and NF
• How do they look like?
• Form of mulberry lesions.
• When are Astrocytic hamartomas
termed giant drusen of optic disc?
• When they are located adjacent to
the ONH, they may closely resemble
ODD.
In what ways do ONH harmatomas
contrast to true ODD?
• originate at the ONH margin, with
extension to the peripapillary retina
• arise in the inner retinal layers and
typically obscure retinal vessels
• may have a fleshy, pinkish
component
• do not autofluoresce and may show
tumor- like vascularity on fluorescein
angiography
183. Congenital optic nerve head anomalies
• Optic nerve hypoplasia
• What’s the Visual acuity in eyes with optic nerve hypoplasia?
• ranges from 20/15 with minimal visual field defects to no light perception.
• nearly all eyes affected by this condition have visual field loss.
• How does the ONH appear here?
• The ONH is small, usually one-half to one-third of normal diameter.
• Comparing the horizontal ONH diameter with the ONH–macula distance may
help in detection.
• The ONH may seem pale, gray, or (less commonly) hyperemic and may be
surrounded by a yellow peripapillary halo, which in turn is bordered by a ring of
increased or decreased pigmentation (the double-ring sign)
185. .
• How do retinal vessels appear here?
• Retinal vessel diameter may seem large
relative to the ONH size, and the vessels
may appear tortuous.
• What are the associations of optic nerve
hypoplasia?
• midline or hemispheric brain defects
• endocrinologic abnormalities (deficiency of
growth hormone and other pituitary
hormones)
• congenital suprasellar tumors.
• Skull-base defects may be associated with
basal encephaloceles.
• What’s the most common syndrome?
• (septo- optic dysplasia or de Morsier
syndrome)
• What does the syndrome entail?
• optic nerve hypoplasia
• absent septum pellucidum
• pituitary dwarfism.
• The corpus callosum may be thinned or
absent.
• Why is an MRI scan recommended in all
cases of optic nerve hypoplasia, and why is
endocrinologic evaluation necessary?
• because hypoglycemic seizures or growth
retardation may develop without
appropriate treatment.
186. .
• What teratogens are associated with optic nerve hypoplasia?
• quinine, ethanol, and anticonvulsants.
• Which variant occurs most often in children of mothers with
diabetes mellitus?
• superior segment hypoplasia
• the affected eyes have a corresponding inferior visual field defect.
187. Congenital tilted disc syndrome
• bilateral (80%)
• What is it usually confused with?
• simple myopic tilted ONHs with
temporal crescent.
• What do you see on examination?
• inferonasal colobomatous
excavation of the nerve tissue,
often associated with thinning of
adjacent RPE and choroid.
• Retinal vessels nasalised
• What do the VF defects of
congenital tilted disc syndrome
mimic?
• They may mimic those of chiasmal
compression
• How can they be differentiated?
• by their failure to respect the vertical
midline and their partial
improvement with myopic refractive
correction.
190. .
• What is optic pit?
• a depression of the ONH surface
• What is its colour?
• often gray or white
• Where is it located?
• Inferotemporally
• Which VF defect is found?
• mild visual field defect (usually
paracentral or arcuate).
• How does Serous detachment of the
macula develop here?
• related to liquefied vitreous entering
the subretinal space through
communication between the optic pit
and the macula.
191. .
• What causes Colobomas of the optic nerve?
• result from incomplete closure of the embryonic fissure
• Where do they usually occur?
• Inferiorly
• How does the dysplastic nerve of papillorenal syndrome or renal
coloboma syndrome appear?
• excavated with absence or attenuation of the central retinal vessels and
multiple cilioretinal vessels emanating and exiting from the ONH edge.
• Visual acuity is often normal, but perimetry may reflect superonasal visual
field defects.
• linked to mutations in the PAX2 gene (which are autosomal dominant).
192. .
• What is the morning glory ONH
anomaly?
• It is a funnel- shaped staphylomatous
excavation of the optic nerve and
peripapillary retina.
• What’s its epidemiology?
• It is more common in females and
usually unilateral.
• How does the ONH appear here?
• The ONH is enlarged, pink or orange,
and either elevated or recessed within
the staphyloma.
• Chorioretinal pigmentation surrounds
the excavation, and white glial tissue is
present on the central ONH surface.
• What is the characteristic feature?
• emanation of retinal vessels from the
periphery of the ONH.
• What complication do we fear here?
• Nonrhegmatogenous serous retinal
detachments
• Why is Neuroimaging warranted?
• to evaluate for a basal encephalocele
and CNS vascular anomalies.
193. Optic Atrophy
• The combination of vision loss, an
RAPD, and optic atrophy is nonspecific
and might represent the chronic phase
of any of the optic neuropathies
described in the previous slides.
• When historical features and clinical
signs do not suggest a specific cause,
what should we do?
• We do baseline studies of optic nerve
function and a screening workup for
treatable causes
• How can we establish the level of
optic nerve function?
• VA
• color vision testing
• quantitative perimetry testing.
• What’s the rationale of Fundus
photography?
• used to document the degree and
pattern of atrophy
• helps the clinician detect subtle
changes in contour over time.
194. .
What do we do with optic atrophy
without a clear cause?
• Neuroimaging, preferably MRI of the
brain and orbits
• Which lab tests are done?
• Screening for syphilis
• vitamin B12 deficiency
• folate deficiency
• Vasculitis
• Sarcoidosis
• heavy- metal toxicity
• When do we do Observation?
• If there are negative results from
testing.
• When do we reassess the initial
testing or do additional testing?
• if the condition worsens or new
findings develop
198. Chiasmal lesions
• Why is visual field loss due to chiasmal
and retrochiasmal lesions characterized
by temporal defects that align along
the vertical meridian?
• Due to the segregation of nasal and
temporal retinal fibers at the chiasm
• What is the most common visual field
defect of chiasmal compression?
• bitemporal hemianopia
• How does the ONH appear in chiasmal
syndromes?
• normal initially, even with significant
visual field loss.
• Early on, peripapillary retinal RNFL
dropout and mild ONH pallor develop.
• Later, the ONHs show typical atrophy,
often in the temporal portion of the
ONH.
• Cupping of the ONH may increase.
• Does a tumor compressing the chiasm
ever produce ONH edema?
• No
199. .
• Which part of the VF is affected first in parasellar lesions?
• The peripheral (temporal) visual fields are usually involved first.
• What happens with an affected optic nerve?
• may cause more central vision loss, with impaired visual acuity,
dyschromatopsia, and an RAPD on the affected side.
200. Visual Field Loss Patterns
• What VF pattern is seen in lesions that injure an optic nerve at its junction
with the optic chiasm?
• cause junctional scotomas.
• Diminished visual acuity and central visual field loss occur in the ipsilateral eye,
and a temporal hemianopia develops in the opposite eye
• What else can be indicated by a unilateral temporal hemianopia that respects
the vertical midline, with no involvement of the visual field in the opposite
eye (also known as a junctional scotoma of Traquair)?
• can also indicate a chiasmal abnormality.
• Presumably, the mass compresses only the crossing nasal fibers from 1 eye.
205. Etiology of Chiasmal Disorders
• How can we classify the lesions of the chiasm?
• extrinsic or intrinsic.
• Extrinsic lesions affecting the chiasm
• What are the most common lesions producing the chiasmal syndrome?
• pituitary adenoma
• parasellar meningioma
• Craniopharyngioma
• parasellar internal carotid artery aneurysm
• ICA aneurysm
• Dilated 3rd ventricle due to obstruction
207. .
• What is the most common cause of
chiasmal compression?
• Pituitary adenomas
• Are they common in childhood?
• No.
• How do patients with nonsecreting
tumors present?
• with vision loss
• No other symptoms.
• How do tumors that actively secrete
hormones (such as prolactin or growth
hormone) present?
• detected before vision loss occurs because
of their systemic endocrine symptoms.
• When can Pituitary tumors enlarge?
• during pregnancy
• What happens after their enlargement?
• produce chiasmal compression.
208. .
• What is pituitary apoplexy?
• Acute hemorrhage or infarction of the
pituitary tumor
• is a potentially life- threatening event
heralded by severe headache, nausea,
and altered consciousness.
• What are the Neuro- ophthalmic
findings here?
• diplopia and loss of vision or visual field
• When do we get dysfunction of CNs III,
IV, V, and VI in this condition?
• After sudden expansion of the tumor
into the adjacent cavernous sinuses
• Which CN is most affected?
• CN III
• What happens after extravasation of
blood into the subarachnoid space?
• a decreased level of consciousness and
vasospasm with secondary stroke.
• Why is the recognition of pituitary
apoplexy so crucial?
• So that prompt neurosurgical treatment
can be done as the acute endocrine
abnormalities may lead to numerous
complications, including adrenal crisis.
210. .
• Which people are most prone to
Parasellar meningiomas?
• middle- aged women.
• Where do they frequently arise
from?
• the tuberculum sella, planum
sphenoidale, or anterior clinoid.
• What clinical feature is classical
here?
• asymmetric bitemporal vision loss.
• How do Parasellar meningiomas behave
during pregnancy?
• may also enlarge and produce chiasmal
compression
• In which age group are Craniopharyngiomas
common?
• in children
• What is the classical VF defect in
Craniopharungiomas?
• inferior bitemporal visual field loss.
211. .
• What so we see in Internal carotid
artery aneurysms, particularly in the
supraclinoid region?
• markedly asymmetric chiasmal
syndrome, with optic nerve compression
on the side of the aneurysm.
• What factors affect Therapy of
parasellar tumors?
• age of the patient
• the nature
• Location
• extent of the tumor
• its hormonal activity
• the severity of symptoms, particularly
the presence of vision loss.
• What are the Treatment modalities in
pituitary apoplexy?
• observation only, if visual field is normal
• surgery (usually transsphenoidal, or
craniectomy)
• medical therapy (primarily
bromocriptine or cabergoline for
prolactin- secreting pituitary tumors)
• radiation therapy (as either a primary or
adjunctive therapy for incompletely
resectable tumors)
212. .
• What do we see after surgical resection of the
tumor and relief of anterior visual pathway
compression?
• vision recovery is usually rapid and may be
dramatic, even in patients who experienced
severe vision loss.
• How effective is Medical therapy for pituitary
adenomas?
• has a slower effect, taking days to weeks
• When is Prognosis is poor?
• if mean RNFL thickness is less than 75 μm, as
revealed on OCT scans
• Why is the ophthalmologist’s role in
the management of parasellar tumors
so crucial?
• because vision loss may be the first sign
of recurrence.
• When should we do Visual field, visual
acuity, and color vision testing?
• 2–3 months after treatment and at
intervals of 6–12 months thereafter,
depending on the course.
• When should Visual acuity and visual
fields be rechecked more often?
• if the patient reports any ongoing
change.
213. .
• What should we think about when we have Delayed vision loss after
therapy for parasellar lesions?
• tumor recurrence
• delayed radionecrosis of the chiasm or optic nerves
• chiasmal distortion due to adhesions or secondary empty sella syndrome
with descent and traction on the chiasm
• chiasmal compression from expansion of intraoperative overpacking of the
sella with fat
• What helps us differentiate these entities?
• Neuroimaging
214. Intrinsic lesions affecting the chiasm
• Give examples:
• infections (eg, tuberculosis, Lyme
disease)
• inflammation (eg, sarcoidosis, MS,
IgG4RD)
• Neoplasms: primary (eg, OPGs) or
secondary (eg, metastasis).
• Traumatic
• What VF defect do we see with
significant closed-head trauma?
Why?
• bitemporal hemianopia, due to
chiasmal injury.
• Can we get chiasmal injury from
parasellar radiation therapy?
• yes
• Why is ischemia of the chiasm very
uncommon?
• due to its robust collateral blood
supply
219. Retrochiasmal lesions
• What makes up the retrochiasmal visual
pathway?
• optic tract; lateral geniculate body; and
temporal, parietal, and occipital lobe visual
radiations
• Describe what happens as the fibers course
through this part
• crossed nasal fibers from the contralateral eye
and uncrossed temporal fibers from the
ipsilateral eye come together.
• What VF defect do we see in Retrochiasmal
damage?
• homonymous visual field defects that continue
to respect the vertical midline.
• Homonymous hemianopia
• What VF defects do we see in lesions of the
optic radiations?
• dissimilar (incongruous) defects in the
corresponding homonymous hemifields
• What VF defects do we see in more posterior
damage?
• progressively similar (congruous) defects as
lesions approach the occipital lobes.
• Should we exclude the possibility of a more
anterior lesion affecting optic tract or LGB
when we have a highly congruous
homonymous hemianopia?
• no
220. .
• Where do we find lesions severe enough to produce complete
hemianopic defects?
• may occur at any anteroposterior retrochiasmal location
• What is the most common cause of homonymous hemianopias?
• Stroke
• What comes next?
• traumatic brain injury and tumor.
• What do we find on ocular exam in retrochiasmal lesions?
• Congruity
• Contralateral RAPD
221. Optic Tract
• What VF defect do we see in lesions of
the optic tract?
• cause homonymous defects in the
hemifields contralateral to the affected
optic tract
• What causes damage to the optic tract?
• mass lesions such as aneurysms or
tumors.
• If optic nerve is involved what type of
RAPD do we find?
• ipsilateral RAPD if the optic nerve is also
involved.
• What type of lesions can we have at the
optic tract?
• Inflammatory
• demyelinating lesions.
• Ischemic lesions of the tract: result from
infarction in the territory of the anterior
choroidal artery. (rare)
• Mass lesions like aneurysms
• What other findings make up the optic
tract syndrome?
• Bow-tie optic atrophy
• Mild RAPD in the contralateral eye
222. .
“Bow-tie” optic atrophy.
• What is this?
• atrophy in the corresponding nasal
and temporal horizontal portions of
the ONH
• What is its other name?
• Band atrophy
• Expound on the origin of this phenomenon
• Since the optic tract involves crossed fibers
from the contralateral eye, the corresponding
atrophy of crossed retinal fibers (those nasal to
the macula) involves the papillomacular fibers
and the nasal radiating fibers in the
contralateral eye
• What is involved in the atrophy in the
ipsilateral eye?
• only the arcuate temporal bundles involved
224. Mild RAPD in the contralateral eye.
• Where does this finding stem from?
• the presence of greater sensitivity of the nasal retina than the
temporal retina
• the presence of more crossed than uncrossed pupillary fibers in the
tract
• Above two cause more pupillary fibers from the contralateral eye to
be damaged by a tract lesion.
225. Lateral Geniculate Body
• Why is it that lesions in the LGB can
cause highly localized visual field
defects?
• It’s a highly organized and layered
retinotopic structure.
• What causes the congruous horizontal
sectoranopia?
• results from disruption within the
vascular distribution of the
posterolateral choroidal artery, a
branch of the posterior cerebral artery.
• When do we see loss of the upper
and lower homonymous quadrants
(also known as quadruple
sectoranopia) with preservation of a
horizontal wedge?
• occurs with disruption of the anterior
choroidal artery, a branch of the
middle cerebral artery
• What rule do these visual field obey?
• defects respect the vertical meridian
227. Temporal Lobe
• Inferior visual fibers course from the LGB
anteriorly in the Meyer loop of the temporal
lobe (approximately 2.5 cm from the anterior
tip of the temporal lobe).
• Superior fibers tend to course more directly
posteriorly in the parietal lobe.
• The lesions affecting the Meyer loop produce
superior, incongruous, homonymous defects
contralateral to the lesion. These defects (so-
called pie in the sky defects) spare fixation
• Damage to the temporal lobe anterior to
the Meyer loop does not cause visual field
loss.
• Lesions affecting the radiations posterior to
the loop produce homonymous
hemianopic defects that extend inferiorly.
• Tumors within the temporal lobe are a
common cause of visual field loss.
• Neurologic findings of temporal lobe lesions
include seizure activity, including olfactory
seizures and formed visual hallucinations.
• Surgical excision of seizure foci in the temporal
lobes may lead to visual field defects.
230. Parietal Lobe
• What often causes the lesions of the
parietal lobe?
• stroke or neoplasms
• Which VF defect do we see here and why?
• contralateral inferior homonymous
hemianopic defects due to superior fibers
being involved first
Pie on the floor
• How do extensive lesions appear?
• involve the superior visual fields but
remain denser inferiorly.
• What is Gerstmann syndrome?
• Lesions of the dominant parietal lobe causing a
combination of acalculia, agraphia, finger
agnosia, and left–right confusion.
• What do we see with lesions in the
nondominant parietal lobe?
• can cause contralateral neglect.
231. .
• What may cause abnormalities in
optokinetic nystagmus (OKN)?
• Damage to pursuit pathways that
converge in the posterior parietal
lobes (near the visual radiations)
• How does the examiner elicit the
impaired OKN response?
• by moving targets toward the lesion,
inducing attempts to use the
damaged pursuit pathway.
• What do we see with a patient having a
homonymous hemianopia due to a parietal
lobe lesion?
• A reduced OKN response with the target
moving toward the affected side
• What do we see in a patient with a
homonymous hemianopia due to a lesion
of the optic tract or occipital lobe?
• An intact OKN response
232. Occipital Lobe
• What becomes more important as the
fibers approach the occipital lobes?
• Congruity
• Hence congruous homonymous
hemianopia
• How do central fibers and peripheral
fibers course?
• Central fibers become separate from
peripheral fibers; the central ones
course to the occipital tip and the
peripheral ones to the anteromedial
cortex.
• Where do we find cortical magnification
corresponding to central vision?
• in the posterior part of the striate cortex
• What does the central 10° of visual field
correspond to?
• approximately 50% of the visual cortex
that extends from the posterior portion
of the medial area to the occipital tip
234. .
• Why is it that some of the peripheral
nasal fibers leading to the
anteromedial region are not
matched with the corresponding
uncrossed fibers?
• Because of the disparity in crossed
versus uncrossed fibers.
• Finally, fibers localize within the
occipital cortex superior and inferior
to the calcarine fissure.
• What does a macula-sparing
homonymous hemianopia
suggest?
• a stroke involving the portion of
the primary visual cortex supplied
by the posterior cerebral artery.
235. .
Explain the above phenomenon
• The tip of the occipital lobe receives a
dual blood supply from the middle
cerebral artery and the posterior
cerebral artery.
• Occlusion of the posterior cerebral
artery damages the primary visual
cortex, except for the region
representing the macula at the
posterior tip of the occipital lobe,
which remains perfused by the middle
cerebral artery
Why does systemic hypoperfusion
often damage the occipital tip?
• because the tip sits in a watershed
area supplied by distal branches of
the posterior and middle cerebral
artery systems.
• When do we have homonymous
hemianopic scotomata?
• when this highly vulnerable region is
the only injured area.
236. .
• When do we get Cerebral blindness?
• From bilateral occipital lobe damage.
• What helps to distinguish cerebral
blindness from total blindness caused
by lesions anterior to the LGB?
• Normal pupillary responses and optic
nerve appearance
• What causes Anton syndrome (denial
of blindness)?
• associated with cortical blindness
• A lesion at any level of the vision system
severe enough to cause blindness.
• When can we find unformed
visual hallucinations?
• Disturbances of the primary
visual cortex due to neoplasms,
migraine, or drugs
• When can we find formed
hallucinations?
• lesions of the extrastriate cortex
or temporal lobe.
237. .
• What is the Riddoch phenomenon?
• Patients with injury to the occipital cortex sometimes perceive moving targets
but not static ones
• What explains the Riddoch phenomenon?
• probably stems from cells in the visual system responding better to moving
stimuli than to those that are static.
246. Vision Rehabilitation
• recognize the impact of vision loss on a patient’s life
• advise the patient of available vision rehabilitation options, including referral
to a rehabilitation specialist.
• An evaluation at a low- vision clinic: orientation and mobility, the patient
education about compensation techniques, such as computer training or use
of prisms.
• Counseling regarding driving: for patients with visual acuity loss or visual field
defects.