strabismus

Focal Dermal Hypoplasia

Clinical Characteristics
Ocular Features: 

Features have considerable heterogeneity and few patients have all of them.  Some ocular abnormalities are found in 40% of patients.  Microphthalmia is common and many patients (30%) have colobomas of the iris and choroid.  Some patients have dislocated lenses.  Distinctive peripheral corneal lesions consisting of discrete vascularized subepithelial opacities have been described.  Occasional patients have conjunctival or lid margin papillomas.  Strabismus and nystagmus are common.

Systemic Features: 

This disorder has a wide variety of clinical features and many occur in only a few patients.  The skin has focal areas of hypoplasia with hypopigmentation, often appearing in a streak or linear pattern.  These areas may be present at birth and contain bullae or urticarial lesions with signs of inflammation.  Telangiectases and herniated fat may appear in these areas.   Oral, esophageal, and laryngeal fibrovascular papillomas occur but they may also be seen in the perineal, vulvar, and perianal areas.  These may be large, friable, and recurrent.  The teeth erupt late and are usually hypoplastic.  The nails are often dysplastic and the hands and feet may be 'split' with syndactyly of the third and fourth fingers giving a 'lobster claw' appearance.  Polydactyly may be present.  Most have thin 'protruding' ears.  A variety of skeletal anomalies have been reported including absence of metatarsals and metacarpals.  A considerable number of patients have mild to moderate mental deficits.  Severely affected females may die in infancy.

Genetics

This is considered an X-linked dominant disorder with lethality in males.  However, numerous affected males (>30) and rare instances of father-to-daughter transmission have been reported and it has been suggested that half-chromatid mutations or postzygotic somatic mosaicism in these males might be responsible.  Mutations in the PORCN gene (Xp11.23) have been associated with FDH.

Pedigree: 
X-linked dominant, mother affected
Treatment
Treatment Options: 

Surgery may be required for the papillomas if they are obstructive.

References
Article Title: 

Cataracts, Congenital, Posterior Polar

Clinical Characteristics
Ocular Features: 

Posterior polar cataracts are likely to occur congenitally but there is often a delay in detection until childhood or even adolescence.  Many patients with a late diagnosis develop nystagmus and strabismus.  Opacification usually begins bilaterally as disc-shaped plaques of opacification in the posterior polar region and progresses relatively rapidly to complete opacification.  Some patients require lens surgery in the first year of life while others not until they are young adults.

Systemic Features: 

This type of congenital cataract is not associated with systemic symptoms.

Genetics

Autosomal dominant posterior polar cataracts may result from mutations in the EPHA2 gene located at 1pter-p36.1.  Interestingly, an area with a likely locus adjacent to but outside the coding region of this gene has been associated with age-related cataracts.

This type of lens opacity may be allelic to Volkmann cataract (115665).

Other forms of autosomal dominantly inherited, congenital, progressive lens opacities include congenital cerulean (115660, 601547, 608983, 610202), Coppock-like (604307), and lamellar (116800) cataracts. Due to clinical heterogeneity, it is not always possible to classify specific families based on the appearance and natural history of the lens opacities alone.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Serial monitoring and timely surgery are important for the prevention of amblyopia, strabismus, and nystagmus.

References
Article Title: 

Night Blindness, Congenital Stationary, CSNB2B

Clinical Characteristics
Ocular Features: 

Night blindness is a feature of many pigmentary and other retinal disorders, most of which are progressive.  However, there is also a group of genetically heterogeneous disorders, with generally stable scotopic defects and without RPE changes, known as congenital stationary night blindness (CSNB).  At least 10 mutant genes are responsible with phenotypes so similar that genotyping is usually necessary to distinguish them.  All are caused by defects in visual signal transduction within rod photoreceptors or in defective photoreceptor-to-bipolar cell signaling with common ERG findings of reduced or absent b-waves and generally normal a-waves.  The photopic ERG is usually abnormal to some degree as well and visual acuity may be subnormal.  In the pregenomic era, subtleties of ERG responses were frequently used in an attempt to distinguish different forms of CSNB.  Genotyping now enables classification with unprecedented precision.

In this disorder (CSNB2B) the b-wave responses are deficient (little or no scotopic response) and a-waves seem to be normal.  However, many if not most patients do not complain of night blindness.  Nystagmus, strabismus, and restriction of visual fields may be present.  Visual acuity is mildly to severely reduced.

Foveal thinning has been documented in this condition.

Systemic Features: 

No systemic disease is associated with congenital stationary night blindness.

Genetics

CSNB2B, or type 2B, is one of four congenital nightblindness disorders with autosomal recessive inheritance.  It results from mutations in the CAPB4 gene (11q13.1) important in receptor to bipolar cell signaling.

Other autosomal recessive CSNB disorders are: CSNB1C (613216), CSNB (unclassified; OMIM number pending), and CSNB1B (257270).

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment beyond correction of the refractive error is available but tinted lenses are sometimes used to enhance vision.

References
Article Title: 

Night Blindness, Congenital Stationary, CSNB2A

Clinical Characteristics
Ocular Features: 

Night blindness is a feature of many pigmentary and other retinal disorders, most of which are progressive.  However, there is also a group of genetically heterogeneous disorders, with generally stable scotopic defects and without RPE changes, known as congenital stationary night blindness (CSNB).  At least 10 mutant genes are responsible with phenotypes so similar that genotyping is usually necessary to distinguish them.  All are caused by defects in visual signal transduction within rod photoreceptors or in defective photoreceptor-to-bipolar cell signaling with common ERG findings of reduced or absent b-waves and generally normal a-waves.  However, the photopic ERG can be abnormal to some degree as well and visual acuity may be subnormal.  In the pregenomic era, subtleties of ERG responses were frequently used in an attempt to distinguish different forms of CSNB.  Genotyping now enables classification with unprecedented precision.

Congenital stationary night blindness disorders are primarily rod dystrophies presenting early with symptoms of nightblindness and relative sparing of central vision.  Nystagmus and photophobia are usually not features.  Dyschromatopsia and loss of central acuity can develop later as the cones eventually become dysfunctional as well but these symptoms are much less severe than those seen in cone-rod dystrophies.  The amount of pigmentary retinopathy is highly variable. 

CSNB2A, or type 2A, is associated with myopia which ranges from mild to severe.  Residual rod function is diminished but not completely absent as suggested by the presence of small b-waves.  Cone function is impacted to some degree as well.  Nystagmus and strabismus are inconsistent findings.  Retinal pigmentation is usually normal in the X-linked forms. Visual acuity ranges from 20/30 to 20/200.  Night blindness is less severe in this form than in another X-linked CSNB (CSNB1A; 310500).  Mild dyschromatopsia is present in some patients but this is primarily a disease of rods.

Systemic Features: 

No systemic disease is associated with congenital stationary night blindness.

Genetics

Congenital stationary night blindness type 2A is an X-linked disorder caused by a mutation in the CACNA1F gene located at Xp11.23.  Only males are affected and carrier females do not have clinical disease.

This disorder is allelic to Aland Island Eye Disease (300600) from which it differs by an apparent lack of progressive myopia and the presence of a normal fovea.  Aland Island Eye Disease has foveal hypoplasia as well as iris and fundus hypopigmentation.

Another allelic disorder with mutations in CACNA1F is CORDX3 (300476), a cone-rod dystrophy.

Approximately 55% of X-linked CSNB are of this type while about 45% have another X-linked form known as CSNB1A, or type 1A (310500) secondary to a mutation at Xp11.4. 

Pedigree: 
X-linked recessive, carrier mother
X-linked recessive, father affected
Treatment
Treatment Options: 

No treatment beyond correction of the refractive error is available but tinted lenses are sometimes used to enhance vision.

References
Article Title: 

Night Blindness, Congenital Stationary, CSNB1C

Clinical Characteristics
Ocular Features: 

Night blindness is a feature of many pigmentary and other retinal disorders, most of which are progressive.  However, there is also a group of genetically heterogeneous disorders, with generally stable scotopic defects and without RPE changes, known as congenital stationary night blindness (CSNB).  At least 10 mutant genes are responsible with phenotypes so similar that genotyping is usually necessary to distinguish them.  All are caused by defects in visual signal transduction within rod photoreceptors or in defective photoreceptor-to-bipolar cell signaling with common ERG findings of reduced or absent b-waves and generally normal a-waves.  The photopic ERG is usually abnormal to some degree as well and visual acuity may be subnormal.  In the pregenomic era, subtleties of ERG responses were frequently used in an attempt to distinguish different forms of CSNB.  Genotyping now enables classification with unprecedented precision.

Congenital stationary night blindness disorders are primarily rod dystrophies presenting early with symptoms of nightblindness and relative sparing of central vision.  Nystagmus and photophobia are usually not features.  Dyschromatopsia and loss of central acuity can develop later as the cones eventually become dysfunctional as well but these symptoms are much less severe than those seen in cone-rod dystrophies.  The amount of pigmentary retinopathy is highly variable. 

In this disorder (CSNB1C) the b-wave responses are severely deficient (no scotopic response) and a-waves seem to be normal.  Some reduction in central acuity is common.  High myopia may be present together with nystagmus and strabismus.  In one family, hypoplastic discs and relative thinning of the inner nuclear layer were described in twin brothers.  ERG responses suggest loss of ON bipolar cell function similar to that found in patients with GRM6 mutations (CSNB1B; 257270).

Systemic Features: 

No systemic disease is associated with congenital stationary night blindness.

Genetics

CSNB1C, or type 1C, is one of four congenital nightblindness disorders with autosomal recessive inheritance.  It results from mutations in the TRPM1 (15q13-q14) gene which encodes for a calcium ion channel protein, part of the GRM6 signaling cascade.  

Other autosomal recessive CSNB disorders are: CSNB2B (610427), CSNB (unclassified; OMIM number pending), and CSNB1B (257270).

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment beyond correction of the refractive error is available but tinted lenses are sometimes used to enhance vision.  Refractive errors need to be corrected and low vision aids can be helpful for those with some loss of central acuity.

References
Article Title: 

Night Blindness, Congenital Stationary, CSNB1A

Clinical Characteristics
Ocular Features: 

Night blindness is a feature of many pigmentary and other retinal disorders, most of which are progressive.  However, there is also a group of genetically heterogeneous disorders, with generally stable scotopic defects and without RPE changes, known as congenital stationary night blindness (CSNB).  At least 10 mutant genes are responsible with phenotypes so similar that genotyping is usually necessary to distinguish them.  All are caused by defects in visual signal transduction within rod photoreceptors or in defective photoreceptor-to-bipolar cell signaling with common ERG findings of reduced or absent b-waves and generally normal a-waves.  The photopic ERG is usually abnormal to some degree as well and visual acuity may be subnormal.  In the pregenomic era, subtleties of ERG responses were frequently used in an attempt to distinguish different forms of CSNB.  Genotyping now enables classification with unprecedented precision.

Congenital stationary night blindness disorders are primarily rod dystrophies presenting early with symptoms of nightblindness and relative sparing of central vision.  Nystagmus and photophobia are usually not features.  Dyschromatopsia and loss of central acuity can develop later as the cones eventually become dysfunctional as well but these symptoms are much less severe than those seen in cone-rod dystrophies.  The amount of pigmentary retinopathy is highly variable. 

CSNB1A, or type 1A, is associated with myopia which ranges from mild to severe.  Rod function is completely absent.  Nystagmus and strabismus are inconsistent findings.   Visual acuity ranges from 20/30 to 20/200.  Retinal pigmentation is usually normal in the X-linked forms.  Night blindness is more severe in this form than in another X-linked CSNB, type 2A (300071). 

Systemic Features: 

No systemic disease is associated with congenital stationary night blindness.

Genetics

Congenital stationary night blindness type 1A is an X-linked disorder caused by a mutation in the NYX gene located at Xp11.4.  Only males are affected and carrier females do not have clinical disease (although homozygous females with typical findings have been described).

Approximately 45% of X-linked CSNB are of this type while about 55% have another X-linked form known as CSNB2A, or type 2A (300071) resulting from a mutation at Xp11.23.  A single patient with high myopia absent night blindness with a mutation in the NYX gene has been reported.

Pedigree: 
X-linked recessive, carrier mother
X-linked recessive, father affected
Treatment
Treatment Options: 

No treatment beyond correction of the refractive error is available but tinted lenses are sometimes used to enhance vision.

References
Article Title: 

Cataracts, Congenital, Facial Dysmorphism, and Neuropathy

Clinical Characteristics
Ocular Features: 

Cataracts, microphthalmia, and microcornea (mean diameter ~7.5 mm) are present at birth and precede the onset of neurological symptoms.  The lens opacities often consist of anterior and posterior subcapsular opacities but the entire lens may be opaque as well.  Some adults have bilateral ptosis.  The pupils are often small and have sluggish responses to light and mydriatics.  Strabismus and horizontal pendular nystagmus are common.  Visual impairment may be severe.

Systemic Features: 

The neuropathy is primarily motor and usually begins in the lower extremities but is progressive and eventually involves the arms as well.  Motor development is slow and walking is often unsteady from the start.  Speaking may not have its onset until 3 years of age.   Mild, nonprogresssive cognitive defects and mental retardation are often present.  Sensory neuropathy with numbness and tingling develops in the second decade.  Mild chorea, upper limb tremor, mild ataxia, and extensor plantar responses may be seen.  Deafness has been described.  Nerve conduction studies and biopsies have documented a demyelinating polyneuropathy while MRIs demonstrate cerebral and spinal cord atrophy which may be seen in the first decade of life.  The MRI in many patients reveals diffuse cerebral atrophy, enlargement of the lateral ventricles and focal lesions in subcortical white matter.  Most individuals have mild cognitive deficits while psychometric testing reveals borderline intelligence in a minority.

Patients are susceptible to acute rhabdomyolysis following viral infections.  Most are severely disabled by the third decade.

The facial dysmorphism appears in childhood and consists of a prominent midface, hypognathism, protruding teeth, and thickening of the lips.  Spinal deformities occur in the majority of individuals along with foot and hand claw deformities.  All patients are short in stature.  Hypogonadotropic hypogonadism is a common feature and females may be infertile.  Amenorrhea is often present by the age of 25-35 years.

Genetics

This is an autosomal recessive disorder found primarily among European Gypsies.  It is caused by mutations in the CTDP1 gene (18q23-qter).  It is sometimes confused with Marinesco-Sjogren syndrome (248800) with which it shares some clinical features but the two are genetically distinct.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Cataracts often require removal in the first decade of life. Scoliosis and foot deformities may benefit from surgical correction.  Supportive care and physical therapy can be helpful.

References
Article Title: 

Linkage to 18qter differentiates two clinically overlapping syndromes: congenital cataracts-facial dysmorphism-neuropathy (CCFDN) syndrome and Marinesco-Sjogren syndrome

Lagier-Tourenne C, Chaigne D, Gong J, Flori J, Mohr M, Ruh D, Christmann D, Flament J, Mandel JL, Koenig M, Dollfus H. Linkage to 18qter differentiates two clinically overlapping syndromes: congenital cataracts-facial dysmorphism-neuropathy (CCFDN) syndrome and Marinesco-Sjogren syndrome. J Med Genet. 2002 Nov;39(11):838-43.

PubMed ID: 
12414825

Congenital cataracts facial dysmorphism neuropathy syndrome, a novel complex genetic disease in Balkan Gypsies: clinical and electrophysiological observations

Tournev I, Kalaydjieva L, Youl B, Ishpekova B, Guergueltcheva V, Kamenov O, Katzarova M, Kamenov Z, Raicheva-Terzieva M, King RH, Romanski K, Petkov R, Schmarov A, Dimitrova G, Popova N, Uzunova M, Milanov S, Petrova J, Petkov Y, Kolarov G, Aneva L, Radeva O, Thomas PK. Congenital cataracts facial dysmorphism neuropathy syndrome, a novel complex genetic disease in Balkan Gypsies: clinical and electrophysiological observations. Ann Neurol. 1999 Jun;45(6):742-50.

PubMed ID: 
10360766

Saethre-Chotzen Syndrome

Clinical Characteristics
Ocular Features: 

The lids are often ptotic and asymmetrically so in keeping with the skull asymmetry.  Strabismus is common.  Optic atrophy, downward slanting lid fissures, epicanthal folds, and dacryostenosis have also been reported.

Systemic Features: 

The skull is acrocephalic and asymmetrical.  The frontal hairline is low.  The external ear and especially the crus of the ear are malformed and the latter is sometimes considered a valuable diagnostic sign.  There is frequently mild soft tissue syndactyly of the third, fourth and fifth toes, and the distal phalanges of the hallux may be bifid.  Syndactyly of the fingers is sometimes present as well.  Clefting of the soft and hard palates is commonly present and a few patients have had joint contractures.  Hearing loss of all types has been reported.  Mental development seems to be normal.  An increased risk of breast cancer has been found among Swedish patients.

SCS is considered to be one of the more common types of syndromic craniosynostosis.

Genetics

Saethre-Chotzen syndrome is caused by mutations in the TWIST1 (10q26) and possibly FGFR2 genes suggesting genetic heterogeneity.  There is also a great deal of clinical heterogeneity.  This syndrome is sometimes confused with Gorlin-Chaudhry-Moss syndrome (233500).  Pedigrees are consistent with autosomal dominant inheritance.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

There is no known treatment except for cranioplasty and repair of palate clefting.

References
Article Title: 

Axenfeld-Rieger Anomaly, Plus

Clinical Characteristics
Ocular Features: 

This rare disorder has ocular features of Rieger anomaly with significant systemic features but different than those found in the Axenfeld-Rieger syndrome.  The iris is hypoplastic and the pupil may be distorted secondary to anterior synechiae.  Schwalbe line is prominent.  There are no reports of glaucoma but this may be biased by the small number of patients reported.  Hypertelorism, prominent eyes and strabismus have been described.  Several patients have had absence of the extraocular muscles.

Systemic Features: 

Hypotonia, lax joints, midface hypoplasia, prominent forehead, and short stature have been described.  Some, but not all patients have a degree of psychomotor retardation.  Mild hearing impairment has been reported.

Genetics

This is likely an autosomal dominant disorder in which mutations of the PITX2 and FOXC1 genes common in Axenfeld-Rieger syndrome have been ruled out.  No locus has been identified.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

No treatment is available.

References
Article Title: 

Duane Retraction Syndrome 1

Clinical Characteristics
Ocular Features: 

Duane retraction syndrome is a clinically and genetically heterogeneous condition with a highly variable phenotype.  Most cases occur sporadically but others are familial and about 30% of affected individuals have other congenital anomalies.  It is also seen as part of other syndromes such as Goldenhar (164210), and Wildervanck (314600).  In the absence of other anomalies, it is called isolated Duane syndrome.  In addition, three types with autosomal dominant inheritance have been defined.  The clinical features are highly variable making distinction difficult.  Intrafamilial variation may be less than interfamilial differences.  Patients with type 1 discussed here are more likely to have esotropia with a head turn to the involved side in unilateral cases whereas those with type 2 are considered more likely to have an exotropia with a head turn toward the uninvolved side. 

This is a congenital and non-progressive strabismus syndrome.  Sporadic cases are mostly unilateral while familial ones are more likely to be bilateral.  The essential features are globe retraction upon adduction with narrowing of the lid fissure, and some limitation of abduction. Vertical deviation during adduction is sometimes seen.  Frank strabismus in primary position is evident in as many as 76% of individuals and a compensatory head turn is often adopted but amblyopia still occurs in at least 10% of individuals.  Females are affected more frequently than males.

At one point the syndrome was considered to be a myopathic disorder based on histologic changes in the lateral rectus but current thought based on MRI and neurohistologic studies favors a neuropathic etiology.  The abducens motor neurons and the sixth nerve may be absent or dysplastic.  Branches of the third nerve may also co-innervate the lateral and medial rectus muscles.  EMG studies have documented simultaneous activation of the two muscles which likely accounts for at least some of the globe retraction.  However, hypoplastic muscles, including the superior oblique, superior rectus, and levator, have also been visualized on MRI.

Systemic Features: 

None.

Genetics

Duane syndrome 1 described here follows an autosomal dominant pattern.  No specific mutant gene has been found but a locus has been identified at 8q13.

Individuals having Duane Retraction Syndrome 2 (DURS2) (604356) are often found in autosomal dominant pedigrees also.  Multiple mutations in CHN1 have been found among such individuals.  Pedigrees consistent with autosomal recessive inheritance have also been reported but the responsible genes are unknown.  Duane Retraction Syndrome (DURS3) (617041) patients with mutations in MAFB may have sensorineural hearing loss.

Features of Duane syndrome are also part of the Duane-Radial Ray Syndrome (607323).

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Various treatments can be useful, ranging from prisms for mild cases to muscle surgery for a severe head turn or vertical deviations.  Patients should be followed carefully in the first decade of life for the onset of amblyopia and appropriate treatment instituted.  Because of the variability in signs, each patient requires individualized treatment.

References
Article Title: 

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