macular cysts

Retinitis Pigmentosa, AR

Clinical Characteristics
Ocular Features: 

The term retinitis pigmentosa is applied to a large group of disorders with great clinical and genetic heterogeneity.  The ocular disease is characterized by night blindness, field constriction, and pigmentary changes in the retina.  The latter is sometimes described as having a ‘bone corpuscle’ appearance with a perivascular distribution.  A ring scotoma is usually evident.  Age of onset and rate of progression is highly variable, even within families.  The rods are impacted early but cone deterioration with loss of central vision usually follows.  Some patients complain of dyschromatopsia and photophobia.  The ERG generally documents this progression but the mfERG shows wide variations in central cone functioning.  Legal blindness is common by the 5thdecade of life or later.  The course of clinical and ERG changes is more aggressive in the X-linked form than in the autosomal dominant disease.  The final common denominator for all types is first rod and then cone photoreceptor loss through apoptosis.

As many as 50% of patients develop posterior subcapsular cataracts.  The vitreous often contains cells and particulate debris.   Retinal arterioles are often attenuated and the optic nerve may have a waxy pallor, especially late in the disease.  Occasional patients have cysts in the macula.  Some patients experience continuous photopsia. 

Systemic Features: 

The ‘simple’ or nonsyndromal type of RP described here has no systemic features.  However, the retinopathy is seen in a number of syndromes and, of course, in some infectious diseases as well.  It is more accurate to label the fundus finding as 'pigmentary retinopathy' in such cases.

Genetics

A significant proportion of RP cases occur sporadically, i.e., without a family history.  Mutations in more than 30 genes cause autosomal recessive RP disorders and these account for more than half of all cases of retinitis pigmentosa.  More than 100 mutations have been identified in the RHO gene (3q21-q24) alone.  Mutations in some genes cause RP in both autosomal recessive and autosomal dominant inheritance patterns.  Compound heterozygosity is relatively common in autosomal recessive disease.  See OMIM 268000 for a complete listing of mutations.

Many genes associated with retinitis pigmentosa have also been implicated in other pigmentary retinopathies.  In addition, numerous phenocopies occur, caused by a variety of drugs, trauma, infections and numerous neurological disorders.  To make diagnosis even more difficult, the fundus findings and ERG responses in nonsyndromic RP in most patients are too nonspecific to be useful for classification. Extensive systemic and ocular evaluations are important and should be combined with genotyping in both familial and nonfamilial cases to determine the diagnosis and prognosis. 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Photoreceptor transplantation has been tried in without improvement in central vision or interruption in the rate of vision loss.  Longer term results are needed.  Resensitizing photoreceptors with halorhodopsin using archaebacterial vectors shows promise in mice.  High doses of vitamin A palmitate slow the rate of vision loss but plasma levels and liver function need to be checked at least annually.  Oral acetazolamide can be helpful in reducing macular edema.

Low vision aids and mobility training can be facilitating for many patients.  Cataract surgery may restore several lines of vision, at least temporarily.

Several pharmaceuticals should be avoided, including isotretinoin, sildenafil, and vitamin E. 

References
Article Title: 

Retinitis Pigmentosa, AD

Clinical Characteristics
Ocular Features: 

Retinitis pigmentosa is a large group of disorders with great clinical and genetic heterogeneity.  The ocular disease is characterized by night blindness, field constriction, and pigmentary changes in the retina.  The later may have a 'bone corpuscle' appearance with a perivascular distribution.  A ring scotoma is sometimes evident.  Age of onset and rate of progression is highly variable, even within families.  The rods are impacted early but cone deterioration with loss of central vision usually follows.  Some patients complain of dyschromatopsia and photophobia.  The ERG generally documents this progression but the mfERG shows wide variations in central cone functioning.  Legal blindness is common by the 5thdecade of life or later.  The course of clinical and ERG changes is more aggressive in the X-linked form than in the autosomal dominant RHO disease.  The final common denominator for all types is first rod and then cone photoreceptor loss through apoptosis.

As many as 50% of patients develop posterior subcapsular cataracts.  The vitreous often contains cells and particulate debris.   Retinal arterioles are often attenuated and the optic nerve may have a waxy pallor, especially late in the disease.  Occasional patients have cysts in the macula.  Some patients experience continuous photopsia.  

Systemic Features: 

The 'simple' or nonsyndromal type of RP described here has no systemic features.  However, the retinopathy is seen in a number of syndromes and, of course, in trauma and in some infectious diseases as well. 

Genetics

A significant proportion of RP cases occur sporadically, i.e., without a family history.  Mutations in more than 25 genes cause autosomal dominant RP disorders and these account for about one-third of all cases of retinitis pigmentosa but there are many more specific mutations.  More than 100 have been identified in the RHO gene (3q21-q24) alone, for example.  Mutations in some genes cause RP in both autosomal recessive and autosomal dominant inhritance patterns.  See OMIM 268000 for a complete listing of mutations.

Many genes associated with retinitis pigmentosa have also been implicated in other pigmentary retinopathies.  In addition numerous phenocopies occur, caused by a variety of drugs, trauma, infections and numerous neurological disorders.  To make diagnosis even more difficult, the fundus findings and ERG responses in nonsyndromic RP in most patients are too nonspecific to be useful for classification. Extensive systemic and ocular evaluations are important and should be combined with genotyping in both familial and nonfamilial cases to determine the diagnosis and prognosis. 

For autosomal dominant retinitis pigmentosa resulting from mutations in RP1, see Retinitis Pigmentosa 1 (180100). 

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Photoreceptor transplantation has been tried in 8 patients without improvement in central vision or interruption in the rate of vision loss.  Longer term results are needed.  Resensitizing photoreceptors with halorhodopsin using archaebacterial vectors shows promise in mice.  High doses of vitamin A palmitate slow the rate of vision loss but plasma levels and liver function need to be checked at least annually.  The use of oral and systemic carbonic anhydrase inhibitors can be helpful in reducing macular edema.

Low vision aids and mobility training can be facilitating for many patients.  Cataract surgery may restore several lines of vision at least temporarily.

Several pharmaceuticals should be avoided, including isotretinoin, sildenafil, and vitamin E. 

References
Article Title: 

Retinitis Pigmentosa 3, X-Linked

Clinical Characteristics
Ocular Features: 

Retinitis pigmentosa is a large group of disorders with great clinical and genetic heterogeneity.  The ocular disease is characterized by night blindness, field constriction, and pigmentary changes in the retina.  The later may have a ‘bone corpuscle’ appearance with a perivascular distribution.  A ring scotoma is sometimes evident.  Age of onset and rate of progression is highly variable, even within families.  In this, an X-linked form of the disease, the first symptoms often appear early in the second decade of life.  The rods are impacted early but cone deterioration with loss of central vision usually follows.  Some patients complain of dyschromatopsia and photophobia.  The ERG generally documents this progression but the mfERG shows wide variations in central cone functioning.  Legal blindness is common by the 4thor 5thdecades of life.  The course of clinical and ERG changes is more aggressive in the X-linked form than in autosomal dominant retinitis pigmentosa disease resulting from RHO mutations.  The final common denominator for all types is first rod and then cone photoreceptor loss through apoptosis.

Up to 50% of adults develop cataracts beginning in the posterior subcapsular area.  The vitreous often contains cells and some patients have cystoid macular edema.  A waxy pallor of the optic nerve is sometimes present especially in the later stages of the disease.

Female carriers generally are asymptomatic but may also have severe RP.  Occasionally they have an unusual tapetal reflex consisting of a ‘beaten metal’ appearance or sometimes scintillating, golden patches. 

Systemic Features: 

There is no systemic disease in ‘simple’ or non-syndromic retinitis pigmentosa but pigmentary retinopathy is associated with a number of syndromes (syndromal RP) e.g.,  Usher syndromes, Waardenburg syndrome, Alport syndrome, Refsum disease, Kerns-Sayre syndrome, abetalipoproteinemia, neuronal ceroid lipofuscinosis, mucopolysaccharidoses types I, II, III, and Bardet-Biedl syndromes

The RPGR gene is important to the normal function of cilia throughout the body.  For this reason disorders resulting from RPGR mutations such as CORDX1 (304020) and this one are sometimes classified as primary ciliary dyskinesias or ciliopathies.  The gene products of the RPGR gene, for example, are localized to connecting cilia of the outer segments of rods and cones and in motile cilia in the airway epithelia.  A subset of families with RP3 have chronic and recurrent upper respiratory infections including sinusitis, bronchitis, pulmonary atelectasis, and otitis media (300455) similar to that seen in the immotile cilia syndrome (244400).  Female carriers in these families have few retinal changes but may suffer recurrent and severe upper respiratory infections similar to hemizygous males.  Severe hearing loss also occurs in both sexes with the RPGR mutations and there is some evidence that this may be a primary sensorineural problem, perhaps in addition to conductive loss from recurrent otitis media.

Genetics

Mutations in more than 100 genes may be responsible for retinitis pigmentosa but sporadic disease occurs as well.  Between 5 and 10% of individuals have X-linked disease.  Perhaps 70% of X-linked RP is caused by mutations in RPGR (Xp11.4) as in this condition.  The same gene is mutant in one form of X-linked cone-rod dystrophy (CORDX1; 304020). These  disorders are sometimes considered examples of X-linked ocular disease resulting from a primary ciliary dyskinesia (244400).

Another form of X-linked RP (RP2) with more choroidal involvement is caused by mutations in the RP2 gene (312600 ; Xp11.23). 

Many genes associated with retinitis pigmentosa have also been implicated in other pigmentary retinopathies.  In addition numerous phenocopies occur, caused by a variety of drugs, trauma, infections and numerous neurological disorders.  To make diagnosis even more difficult, the fundus findings and ERG responses in nonsyndromic RP in most patients are too nonspecific to be useful for classification. Extensive systemic and ocular evaluations are important and should be combined with genotyping in both familial and nonfamilial cases to determine the diagnosis and prognosis. 

Treatment
Treatment Options: 

Photoreceptor transplantation has been tried in 8 patients without improvement in central vision or interruption in the rate of vision loss.  Longer term results are needed.  Resensitizing photoreceptors with halorhodopsin using archaebacterial vectors shows promise in mice.  High doses of vitamin A palmitate slow the rate of vision loss but plasma levels and liver function need to be checked at least annually.  Oral acetazolamide can be helpful in reducing macular edema.

Low vision aids and mobility training can be facilitating for many patients.  Cataract surgery may restore several lines of vision at least temporarily.

Several pharmaceuticals should be avoided, including isotretinoin, sildenafil, and vitamin E. 

References
Article Title: 

Retinoschisis, Juvenile

Clinical Characteristics
Ocular Features: 

Retinoschisis is a retinal disorder characterized by a cystic degeneration of the retina, leading to a split of retinal layers mainly at the level of the nerve fiber layer. Almost all patients have macular involvement, most commonly with foveal spoke-like streaks consisting of microcystic cavities that may coalesce over time. Retinal pigment epithelium atrophy and pigment clumping may occur.  Peripheral schisis is evident in about 50% of patients with large bullous cavities that may resolve spontaneously leaving a pigmented demarcation line. Other retinal findings are white retinal flecks, exudative retinopathy with retinal detachment, perivascular sheathing and dendritiform vessels in the periphery. Vitreous veils are commonly seen that are caused by separation of the thin inner wall of a peripheral schisis cavity and inner wall holes. Bridging vessels may rupture into the cystic cavity or the vitreous. The onset of the disorder has been detected as early as three months, but the majority of cases are five years old or older. Many present with mildly decreased vision that cannot be corrected with glasses and the diagnosis is often delayed. Visual acuity is highly variable ranging from 20/20 to 20/200, but may decline with age and with complications such as vitreous hemorrhage and macular detachment.  The disorder is also associated with axial hyperopia, posterior subcapsular cataract and strabismus. Fluorescein angiography shows minimal or no leakage as opposed to cystoid macular edema. Focal areas of vascular leakage into schisis cavity may be present as well as peripheral capillary nonperfusion. Electroretinograms exhibit a reduced b-wave and a preserved a-wave.

Systemic Features: 

No general systemic manifestations are associated with juvenile retinoschisis.

Genetics

Juvenile retinoschisis is an X-linked recessive disorder that affects mainly males. The causative mutations involve the gene RS1 located on the X chromosome at Xp22. Female carriers may have peripheral schisis amd many allelic variants have been reported.  The encoded protein retinoschisin is a secreted protein produced by photoreceptors and bipolar cells and may be involved in cell-cell adhesion or ion channel regulation.

Treatment
Treatment Options: 

There is presently no effective treatment for the disorder, but decreased vision later in life can be aided with low vision aids. Cases with posterior subcapsular cataract can be treated with cataract extraction.  Improvement in the cystic macular lesions, central foveal zone thickness, and visual acuity have been reported to benefit from topical dorzolamide treatment.

References
Article Title: 

Peripheral fundus findings in X-linked retinoschisis

Fahim AT, Ali N, Blachley T, Michaelides M. Peripheral fundus findings in X-linked retinoschisis. Br J Ophthalmol. 2017 Mar 27. pii: bjophthalmol-2016-310110. doi: 10.1136/bjophthalmol-2016-310110. [Epub ahead of print].

PubMed ID: 
28348004

X-linked retinoschisis: an update

Sikkink SK, Biswas S, Parry NR, Stanga PE, Trump D. X-linked retinoschisis: an update. J Med Genet. 2007 Apr;44(4):225-32. 2006 Dec 15.

PubMed ID: 
17172462

Goldmann-Favre Syndrome/ESCS

Clinical Characteristics
Ocular Features: 

Enhanced S-cone syndrome, sometimes called Goldman-Favre syndrome, is a retinal disorder characterized by increased sensitivity to blue light, night blindness from an early age, and decreased vision.  Additional features include an optically empty liquefied vitreous, progressive foveal or peripheral retinoschisis, macular cysts, chorioretinal atrophy and pigmentary retinopathy as well as posterior subcapsular cataract formation.  Hyperopia is a feature, at least in childhood.   Enhanced S-cone syndrome is the only retinal disorder that has a gain of a subtype of photoreceptors, in this case the S-cones (short wave length) that detect blue light. Rod photoreceptors and red and green cone receptors are degenerated to a variable degree. Electroretinography shows an extinct rod photoreceptor response and hypersensitivity to shorter wavelengths.

There is considerable variation in the clinical features of NR2E3 mutations which has led to some confusion in the nosology.  Some cases are called juvenile retinoschisis, others are called retinitis pigmentosa, or clumped pigment retinopathy.  Central acuity ranges from near normal (20/40) in young people to 20/200 or worse especially in older adults.  Visual field constriction likewise varies from patient to patient.  Retinal pigmentary changes and the amount of cystic changes in the macula are somewhat age dependent.

Systemic Features: 

No general systemic manifestations are associated with enhanced S-cone syndrome and Goldman-Favre syndrome.

Genetics

This is an autosomal recessive retinal disorder caused by mutations in NR2E3, also known as PNR, located on chromosome 15q23.  It is a part of a transcription factor complex necessary for the development of photoreceptors.  Mutations in NR2E3 cause degeneration of rod photoreceptors and an increased number of S-cone photoreceptors resulting in an increased ratio of blue to red-green cone photoreceptors. Mutations in the NR2E3 gene can also cause a clinical picture resembling simple autosomal recessive retinitis pigmentosa.

Two brothers with an enhanced S-cone phenotype and normal rod function have been reported.  Scotopic b-wave ERG amplitudes were normal but OCT showed flattening of the macular area and thinning of the photoreceptor layer.  This may be the result of a different mutation in this family but no molecular defect was found.

Several Moroccan families have been reported with homozygous or compound heterozygous mutations in the NRL gene (162080).

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

There is presently no effective treatment for the disorder, but visual function can be improved with low vision aids. Cataract surgery may be beneficial.

Improvement in vision has been reported with the use of topical carbonic anhydrase inhibitors.

References
Article Title: 

Expanded Clinical Spectrum of Enhanced S-Cone Syndrome

Yzer S, Barbazetto I, Allikmets R, van Schooneveld MJ, Bergen A, Tsang SH, Jacobson SG, Yannuzzi LA. Expanded Clinical Spectrum of Enhanced S-Cone Syndrome. JAMA Ophthalmol. 2013 Aug 29.  [Epub ahead of print] PubMed PMID: 23989059.

PubMed ID: 
23989059

Phenotypic variation in enhanced S-cone syndrome

Audo I, Michaelides M, Robson AG, Hawlina M, Vaclavik V, Sandbach JM, Neveu MM, Hogg CR, Hunt DM, Moore AT, Bird AC, Webster AR, Holder GE. Phenotypic variation in enhanced S-cone syndrome. Invest Ophthalmol Vis Sci. 2008 May;49(5):2082-93.

PubMed ID: 
18436841
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