[Overview of Congenital Stationary Night Blindness with Predominantly Normal Fundus Appearance]. / Überblick über die kongenitale stationäre Nachtblindheit mit überwiegend normalem Fundus.

Congenital stationary night blindness (CSNB) is a clinically and genetically heterogeneous group of non-progressive retinal disorder with largely normal fundus appearance. The mode of inheritance can be autosomal dominant (adCSNB), autosomal recessive (arCSNB) or X-chromosomal (XLCSNB). Additional ocular signs can be myopia, hyperopia, strabismus, nystagmus and reduced visual acuity. The Riggs and Schubert-Bornschein form of CSNB can be discriminated by electroretinography. While the Riggs form represents a dysfunction of the rods, a signal transmission defect from photoreceptors to bipolar cell is described in patients with the more frequently occurring Schubert-Bornschein form. The Schubert-Bornschein form can be further divided into incomplete (icCSNB) and complete (cCSNB) showing different electroretinograms (ERGs). While patients with cCSNB show a dysfunction of the ON-signaling pathway, patients with icCSNB show a dysfunction of the ON- and OFF-signaling pathways, affecting visual acuity as well. Using classical linkage, candidate gene analyses and more recent next-generation sequencing approaches, to date, mutations in 13 different genes have been associated with this disease. In vitro and in vivo models showed a correlation of the phenotype of patients with the expression, protein localization and function of the respective molecules: genes, mutated in patients with the Riggs form of CSNB have an important role in the rod phototransduction cascade. Genes mutated in patients with icCSNB, code for proteins important for glutamate neurotransmitter release at the synaptic cleft of the photoreceptors. Genes mutated in patients with cCSNB, code for proteins important for glutamate uptake and further signal transmission to the ON-bipolar cells. Preliminary in vivo studies showed that CSNB may be cured by gene therapy. These studies concerning CSNB are important for the precise diagnosis of patients with this disease, but are also helpful in deciphering key molecules essential for signal transmission from photoreceptors to bipolar cells. So far, it is a poorly understood field.

Accuracy of Diagnostic Imaging Modalities for Classifying Pediatric Eyes as Papilledema Versus Pseudopapilledema.

PURPOSE: To identify the most accurate diagnostic imaging modality for classifying pediatric eyes as papilledema (PE) or pseudopapilledema (PPE). DESIGN: Prospective observational study. SUBJECTS: Nineteen children between the ages of 5 and 18 years were recruited. Five children (10 eyes) with PE, 11 children (19 eyes) with PPE owing to suspected buried optic disc drusen (ODD), and 3 children (6 eyes) with PPE owing to superficial ODD were included. METHODS: All subjects underwent imaging with B-scan ultrasonography, fundus photography, autofluorescence, fluorescein angiography (FA), optical coherence tomography (OCT) of the retinal nerve fiber layer (RNFL), and volumetric OCT scans through the optic nerve head with standard spectral-domain (SD OCT) and enhanced depth imaging (EDI OCT) settings. Images were read by 3 masked neuro-ophthalmologists, and the final image interpretation was based on 2 of 3 reads. Image interpretations were compared with clinical diagnosis to calculate accuracy and misinterpretation rates of each imaging modality. MAIN OUTCOME MEASURES: Accuracy of each imaging technique for classifying eyes as PE or PPE, and misinterpretation rates of each imaging modality for PE and PPE. RESULTS: Fluorescein angiography had the highest accuracy (97%, 34 of 35 eyes, 95% confidence interval 92%-100%) for classifying an eye as PE or PPE. FA of eyes with PE showed leakage of the optic nerve, whereas eyes with suspected buried ODD demonstrated no hyperfluorescence, and eyes with superficial ODD showed nodular staining. Other modalities had substantial likelihood (30%-70%) of misinterpretation of PE as PPE. CONCLUSIONS: The best imaging technique for correctly classifying pediatric eyes as PPE or PE is FA. Other imaging modalities, if used in isolation, are more likely to lead to misinterpretation of PE as PPE, which could potentially result in failure to identify a life-threatening disorder causing elevated intracranial pressure and papilledema.

An evaluation of fundus photography and fundus autofluorescence in the diagnosis of cuticular drusen.

PURPOSE: To examine non-mydriatic fundus photography (FP) and fundus autofluorescence (FAF) as alternative non-invasive imaging modalities to fluorescein angiography (FA) in the detection of cuticular drusen (CD). METHODS: Among 2953 adults from the Danish Rural Eye Study (DRES) with gradable FP, three study groups were selected: (1) All those with suspected CD without age-related macular degeneration (AMD) on FP, (2) all those with suspected CD with AMD on FP and (3) a randomly selected group with early AMD. Groups 1, 2 and 3 underwent FA and FAF and group 4 underwent FAF only as part of DRES CD substudy. Main outcome measures included percentage of correct positive and correct negative diagnoses, Cohen's κ and prevalence-adjusted and bias-adjusted κ (PABAK) coefficients of test and grader reliability. RESULTS: CD was correctly identified on FP 88.9% of the time and correctly identified as not being present 83.3% of the time. CD was correctly identified on FAF 62.0% of the time and correctly identified as not being present 100.0% of the time. Compared with FA, FP has a PABAK of 0.75 (0.60 to 1.5) and FAF a PABAK of 0.44 (0.23 to 0.95). CONCLUSIONS: FP is a promising, non-invasive substitute for FA in the diagnosis of CD. FAF was less reliable than FP to detect CD.

Inherited macular dystrophies and differential diagnostics.

The inherited macular dystrophies are characterized by different grade central visual loss and different character macula atrophy, because of retinal pigment epithelium lesion. The cause of photoreceptors degeneration is still not known. In this article, we review subjective and objective ophthalmological examines essential to diagnosis and differential diagnosis of inherited autosomal dominant and autosomal recessive macular dystrophies. It is known seven gene mutations (ABCA4, ELOVL4, PROML1, VMD2, Peripherin/RDS, TIMP3, XLRS), which may cause inherited macular dystrophies development. Inheritance type of inherited macular dystrophies, prevalence, beginning of disease, spread of the disease between female and male, clinic, electroretinography, electrooculography, differential diagnosis, genetic research and prognosis are also reviewed.

Congenital corneal opacities - a surgical approach to nomenclature and classification.

The classification system of congenital corneal opacification (CCO) may be better considered from a perspective of pathogenesis, surgical intervention, and prognosis. The author feels that CCO is best considered as being primary and secondary. Primary CCO includes corneal dystrophies and choristomas presenting at birth. Secondary CCO may be best considered as cases of kerato-irido-lenticular dysgenesis (KILD) and other secondary causes including infection, iatrogenic, developmental anomalies of the iridotrabecular system or lens or both, and developmental anomalies of the adnexal. The appropriate classification may help determine prognosis of any surgical intervention. Terminology is crucial to furthering our understanding of the formation of the anterior chamber if we are to do so by studying cases of CCO. Peters' anomaly is too imprecise a term to describe cases of CCO. This classification of primary and secondary CCO with its subclassifications cannot be made by clinical examination alone and necessitates other diagnostic assessments. It is time to only accept studies of CCO genotype/phenotype correlation for publication if there is clinical phenotype augmented by anterior segment imaging (OCT or high-frequency ultrasound) or histology or both.

Neuro-ophthalmic genetics.

Mutations in nuclear or mitochondrial DNA may cause disorders of neuro-ophthalmic significance. These include disorders of the optic nerve, such as Leber's hereditary optic neuropathy and Kjer-type optic atrophy, and disorders of ocular motility, such as congenital nystagmus, autosomal dominant progressive external ophthalmoplegia, and oculopharyngeal muscular dystrophy. In addition to more accurate disease classification and diagnosis, identification of genetic loci, genes, and their mutations has stimulated investigation into factors influencing disease expression and penetrance.

Molecular elucidation of hereditary eye diseases: pivotal role of the clinician.

For the diagnosis and molecular elucidation of many hereditary eye diseases, the chromosomal localization of the respective gene defects has been instrumental. Given the rapid progress of the global efforts to sequence the entire human genome and in view of new molecular strategies and resources to identify disease genes, further progress in this field will crucially depend on the unambiguous clinical classification of these disorders and on the ascertainment of well-characterized patients and their families. This article deals with conceptual, methodological and logistic aspects of genotype-phenotype analyses aiming at the elucidation of hereditary eye diseases. It stresses the importance of the clinical input in this field which is no longer dominated by molecular genetics.

Ocular amyloidosis, with special reference to the hereditary forms with vitreous involvement.

The complex of diseases referred to as amyloidosis is characterized by the deposition of amyloid substance in various tissues. The amyloid protein differs in the various forms of amyloidosis. This variation is the basis of the differences in affected tissues and subsequent clinical dissimilarities. Vitreous involvement in amyloidosis seems to be especially linked to some of the hereditary neuropathies associated with the amyloid protein transthyretin. Characterization of the amyloid proteins during recent decades has allowed a chemical and immunologic classification of amyloid fibrils. This paper presents the basis for classification of amyloidosis, reviews the literature on ocular amyloidosis, with special reference to vitreous involvement, and summarizes clinical findings and frequency of vitreous amyloid involvement in Swedish patients with familial amyloidotic polyneuropathy.