empty vitreous

Vitreoretinal Degeneration, Snowflake Type

Clinical Characteristics
Ocular Features: 

The retina and vitreous are primarily affected in this disorder.  The age of onset is unknown but characteristic signs can be seen early in the second decade of life.   Early changes include thickening of the cortical vitreous and white dots in the superficial layers of the retina.  The latter are minute yellow-white crystalline deposits more common in the peripheral retina.  Many (83%) patients have early onset cataracts.  Corneal guttae are common (80% of patients).  The vitreous undergoes fibrillar degeneration with liquefaction and eventually appears optically empty.  Many patients experience symptoms of floaters.  The vitreous changes most closely resemble that seen in Wagner syndrome (143200) but with important differences.  In the latter disorder the vitreous changes are membranous, the retinal changes are deeper in location, RPE changes are evident, the choroid and RPE are involved, and the risk of retinal detachment is much higher.  Only 21% of patients with snowflake vitreoretinal degeneration have retinal detachments compared with about 50% in Wagner syndrome.  Retinal vasculature change such as perivascular sheathing and attenuation of arterioles may be seen in both disorders but occur far less commonly in snowflake degeneration.

Based on lack of visual symptoms, the photoreceptors are minimally involved.  Electrophysiologic studies reveal an elevated dark adaptation and reduced scotopic B waves.  Most patients retain excellent vision.  However, the optic nerve may have a waxy pallor and frequently appears flat and lacks a visible cup. 

Systemic Features: 

None.

Genetics

Snowflake vitreoretinal degeneration is an autosomal dominant disorder.   Heterozygous missense mutations have been found in KCNJ13 (2q37) in a single family.  Mutations in the same gene have been identified in rare cases of Leber congenital amaurosis.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Visually significant cataracts may be removed.  Patients need to be observed throughout life to enable prompt intervention when retinal detachments occur.

References
Article Title: 

Wagner Syndrome

Clinical Characteristics
Ocular Features: 

This is one of several hereditary vitreoretinal degenerative disorders in which vitreous degeneration occurs and the risk of retinal detachment is high (others being Goldmann-Favre [268100], Stickler [609508, 108300], and Marshall [154780] syndromes).  An optically empty central vitreous is a common feature in this heterogeneous group.  Other reported ocular findings in Wagner syndrome include perivascular sheathing and pigmentation, progressive chorioretinal dystrophy, ectopic fovea with pseudoexotropia, tractional retinal detachments, glaucoma (neovascular in some), and vitreous veils with fibrillar condensation.  Cataracts occur in virtually all patients over the age of 45 years.  The ERG in the majority of patients shows elevated rod and cone thresholds on dark adaptation (63%) and subnormal b-wave amplitudes (87%).  Mild difficulties in dim light are noted by some patients.  Visual acuities are highly variable ranging from normal in many patients to blindness in others.  Peripheral visual fields may be severely constricted.

Systemic Features: 

Cleft palate has been seen in some patients but these likely had Stickler syndrome (609508, 108300, 604841 ) since hearing loss along with other joint and skeletal manifestations are absent.  Further, cases reported to have Wagner syndrome with palatoschisis have not been genotyped so it is likely that they were misdiagnosed.

Genetics

Wagner syndrome results from a mutation in the VCAN gene encoding versican (5q14.3), a chondroitin sulfate proteoglycan-2 found in the vitreous among other tissues.  It is an autosomal dominant disorder.  It has been proposed that erosive vitreoretinopathy (ERVR) (143200) is allelic to Wagner’s syndrome but it may also simply be a variable expression of the same disorder.  Both map to 5q13-q14.  Overlapping of clinical signs and symptoms among hereditary disorders of vitreoretinal degeneration has created some confusion in their classification but this will hopefully be clarified as more families are genotyped.  Stickler syndrome (609508, 108300), for example, is known to be caused by a mutation in an entirely different gene (COL2A1) on a different chromosome.

Snowflake type vitreoretinal degeneration (193230), another autosomal dominant disorder, has a superficial resemblance but mutations in a different gene (KCNJ13) are responsible.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

There is no therapy specifically for this disorder but the usual treatments for retinal detachments, cataract and glaucoma should be applied where appropriate.

References
Article Title: 

Stickler Syndrome, Type I

Clinical Characteristics
Ocular Features: 

High myopia and vitreous degeneration dominate the ocular manifestations of Stickler syndrome, type I.  The vitreous often appears optically empty as it liquefies and the fibrils degenerate.  The vitreous is sometimes seen to form 'veils', especially in the retrolenticular region but they may also float throughout the posterior chamber.  They are often attached to areas of lattice degeneration in the retina as well as other areas.  Posterior vitreous detachments are common.  Vitreoretinal degeneration is progressive and by the second decade rhegmatogenous detachments occur in half of affected patients.  As many as three quarters of adult patients have retinal breaks.  The retina has pigmentary changes with deposition circumferentially near the equator and more peripherally.  Hypopigmentation is more common early creating a tessellated appearance.  Lenticular opacities occur also early with cortical flecks and wedge-shaped changes.

The ERG may be normal early but evidence of rod and cone dysfunction soon appears and is progressive.  Dark adaptation is defective later in the course of the disease.  The EOG is virtually always depressed.  The visual field is constricted and may show a ring scotoma coincident with the equatorial chorioretinal atrophy.

Glaucoma is not uncommon and may be infantile in onset and difficult to control.  

Phthisis is a significant risk especially for individuals who have multiple surgical procedures for retinal detachments. 

Systemic Features: 

It has been suggested that there is a nonsyndromic or ocular type of Stickler syndrome lacking many of the extraocular features characteristic of the complete syndrome.  However, the evidence for the ocular type described here as a distinct entity remains slim and the clinical picture may simply reflect variable expressivity of mutations in the same gene.  Type I Stickler syndrome has multiple systemic features such as cleft palate, hearing impairment, premature arthritis, micrognathia, kyphoscoliosis, and some signs such as arachnodactyly that are found in the Marfan syndrome.

Genetics

This is an autosomal dominant disease of collagen formation as a result of mutations in the COL2A1 gene (12q13.11-q13.2). The mutations causing both syndromal and the suggested nonsyndromal ocular type of Stickler disease are in the same gene.  Mutations in the same gene are known to cause autosomal dominant rhegmatogenous retinal detachments in patients who have none of the systemic clinical signs (609508).  These patients may lack the signs of vitreous degeneration seen in Kniest dysplasia (156550)  and in the disorder described here.

There is better evidence for a second type of Stickler syndrome, STL2 or type II (604841) based on phenotypic differences and the fact that a second locus (1p21) containing mutations in COL11A1 has been linked to it. 

Type III is caused by mutations in COL11A2 and has systemic features similar to types I and II but lacks the eye findings since this gene is not expressed in the eye.

Type IV also has important ocular features but is an autosomal recessive disorder caused by mutations in COL9A2.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

The combination of progressive vitreoretinal degeneration, frequency of posterior vitreous detachments, and axial myopia creates a lifelong threat of retinal tears and detachments.   Half to three quarters of all patients develop retinal tears and detachments.  Certainly all patients with Stickler syndrome deserve repeated and thorough retinal exams throughout their lives.  In addition to prompt treatment of tears and detachments, some have advocated prophylactic scleral banding to reduce vitreous traction, or applying 360 degree cryotherapy.

References
Article Title: 

Stickler syndrome in children: a radiological review

McArthur N, Rehm A, Shenker N, Richards AJ, McNinch AM, Poulson AV, Tanner J, Snead MP, Bearcroft PWP. Stickler syndrome in children: a radiological review. Clin Radiol. 2018 Apr 13. pii: S0009-9260(18)30118-1. doi: 10.1016/j.crad.2018.03.004. [Epub ahead of print].

PubMed ID: 
29661559

High efficiency of mutation detection in type 1 stickler syndrome using a two-stage approach: vitreoretinal assessment coupled with exon sequencing for screening COL2A1

Richards AJ, Laidlaw M, Whittaker J, Treacy B, Rai H, Bearcroft P, Baguley DM, Poulson A, Ang A, Scott JD, Snead MP. High efficiency of mutation detection in type 1 stickler syndrome using a two-stage approach: vitreoretinal assessment coupled with exon sequencing for screening COL2A1. Hum Mutat. 2006 Jul;27(7):696-704. Erratum in: Hum Mutat. 2006 Nov;27(11):1156.

PubMed ID: 
16752401
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