Shared Features in Retinal Disorders With Involvement of Retinal Pigment Epithelium

Distinguishing ABCA4 from PRPH2-related disease: qualitative analysis of examination and imaging features

INTRODUCTION

ABCA4 and PRPH2-related diseases are both phenotypically heterogeneous and clinically difficult to differentiate. There may be examination and imaging features that can aid in establishing a clinical diagnosis.

METHODS

A single-center, retrospective, consecutive case series including patients with a molecular confirmation of pathologic variants in either the ABCA4 or PRPH2 were included. Chi-square analysis, Fisher exact test, and Student's t-test comparing prevalence of specific examination and imaging features between ABCA4 and PRPH2.

RESULTS

Of the 127 eyes from 64 patients included, the ABCA4 group was more significantly associated with peripapillary sparing on both fundus imaging (73% vs. 40%; p = 0.006) and FAF (71% vs. 44%; p = 0.025), macular (64% vs. 12%; p < 0.001) and peripheral pisciform flecks (22% vs. 3.6%; p = 0.025). The PRPH2 group was more highly associated with macular chorioretinal atrophy (86% vs. 55%; p = 0.003).

CONCLUSIONS

Peripapillary sparing and pisciform flecks are more highly associated with ABCA4-related disease, while macular chorioretinal atrophy is more highly associated with PRPH2-related disease. Logistic regression demonstrates that bull's eye maculopathy and macular flecks are predictive of the ABCA4 genotype.

Near-Infrared Autofluorescence: Early Detection of Retinal Pigment Epithelial Alterations in Inherited Retinal Dystrophies

Near-infrared autofluorescence (NIA) is a non-invasive retinal imaging technique used to examine the retinal pigment epithelium (RPE) based on the autofluorescence of melanin. Melanin has several functions within RPE cells. It serves as a protective antioxidative factor and is involved in the phagocytosis of photoreceptor outer segments. Disorders affecting the photoreceptor-RPE complex result in alterations of RPE cells which are detectable by alterations of NIA. NIA allows us to detect early alterations in various chorioretinal disorders, frequently before they are ophthalmoscopically visible and often prior to alterations in lipofuscin-associated fundus autofluorescence (FAF) or optical coherence tomography (OCT). Although NIA and FAF relate to disorders affecting the RPE, the findings for both imaging methods differ and the area involved has been demonstrated to be larger in NIA compared to FAF in several disorders, especially inherited retinal dystrophies (IRDs), indicating that NIA detects earlier alterations compared to FAF. Foveal alterations can be much more easily detected using NIA compared to FAF. A reduced subfoveal NIA intensity is the earliest sign of autosomal dominant Best disease, when FAF and OCT are still normal. In other IRDs, a preserved subfoveal NIA intensity is associated with good visual acuity. So far, the current knowledge on NIA in IRD has been presented in multiple separate publications but has not been summarized in an overview. This review presents the current knowledge on NIA in IRD and demonstrates NIA biomarkers.

RDH5 and RLBP1-Associated Inherited Retinal Diseases: Refining the Spectrum of Stationary and Progressive Phenotypes

PURPOSE

To investigate the clinical, functional, and imaging characteristics in patients affected by inherited retinal diseases associated with RDH5 and RLBP1 gene variants, and to report novel genotype-phenotype correlations.

DESIGN

Retrospective single-center cohort study.

METHODS

Twenty-two patients with molecularly confirmed RLBP1-associated retinopathy and 5 with RDH5-associated retinopathy. Medical records were reviewed to obtain data on family history and ophthalmologic examinations, including retinal imaging and full-field electroretinography (ffERG). Genotype was determined by targeted next-generation sequencing followed by confirmation and familial segregation by Sanger sequencing.

RESULTS

The median (interquartile ranges) age at baseline for the RDH5 and RLBP1 cohort was 44.6 (38.2-67.9) years and 36.9 (23.1-45.2) years, respectively. Macular atrophy (MA) was found in approximately 80% of eyes from both cohorts. The RLBP1 genotype was associated with a lower macular volume by 0.28 mm3 (95% CI, -0.46 to -0.11; P = .005) compared to the RDH5 genotype. In both genotypic cohorts, we found a significant annual rate of macular volume loss, estimated at -0.007 mm3/y (95% CI, -0.012 to -0.001; P = .02), without any significant difference between the two genotypes. Three unrelated patients homozygous for the c.361C>T p.(Arg121Trp) RLBP1 variant showed minimal impairment of both the rod and cone systems function on ffERG and absence of MA.

CONCLUSIONS

Progressive MA in addition to congenital night blindness can be identified in adult patients with RDH5-associated retinopathy. Vice versa, hypomorphic RLBP1 variants may cause milder retinal phenotypes rather than the typical severe rod-cone dystrophy with MA. These findings could prove beneficial to improve the prognostication of patients and help in designing future interventional trials.

Mechanobiological implications of age-related remodelling in the outer retina

The outer retina consists of the light-sensitive photoreceptors, the pigmented epithelium, and the choroid, which interact in a complex manner to sustain homeostasis. The organisation and function of these cellular layers are mediated by the extracellular matrix compartment named Bruch's membrane, situated between the retinal epithelium and the choroid. Like many tissues, the retina experiences age-related structural and metabolic changes, which are relevant for understanding major blinding diseases of the elderly, such as age-related macular degeneration. Compared with other tissues, the retina mainly comprises postmitotic cells, making it less able to maintain its mechanical homeostasis over the years functionally. Aspects of retinal ageing, like the structural and morphometric changes of the pigment epithelium and the heterogenous remodelling of the Bruch's membrane, imply changes in tissue mechanics and may affect functional integrity. In recent years, findings in the field of mechanobiology and bioengineering highlighted the importance of mechanical changes in tissues for understanding physiological and pathological processes. Here, we review the current knowledge of age-related changes in the outer retina from a mechanobiological perspective, aiming to generate food for thought for future mechanobiology studies in the outer retina.

Typical and atypical clinical presentations of X-Linked retinoschisis: A case series and literature review

X-linked retinoschisis (XLRS) is an X-linked inherited retinal dystrophy characterized by mild-to-severe visual impairment, splitting of the retinal layers, and a reduction in the dark-adapted b-wave amplitude on the electroretinogram. Typical clinical features include macular and peripheral schisis. Relatively common features reported include rhegmatogenous or tractional retinal detachment, vitreous hemorrhage, retinal pigment epithelial changes, vitreous veils, and various retinal vascular abnormalities with or without exudation. Macular hole and macular folds are atypical presentations of XLRS, along with several other rare findings. Here, we report 4 cases of XLRS with atypical clinical presentations and review the literature on XLRS, with a focus on the variable clinical features of this condition.

Nahinfrarot-Autofluoreszenz: klinische Anwendung und diagnostische Relevanz

Die Nahinfrarot-Autofluoreszenz (NIA) ist ein nicht-invasives Verfahren zur Untersuchung des retinalen Pigmentepithels (RPE) basierend auf der Darstellung des antioxidativen Schutzfaktors Melanin in den RPE-Zellen. Die NIA verbessert die Früherkennung chorioretinaler Erkrankungen, da bei vielen dieser Erkrankungen mit der NIA Strukturveränderungen des RPE nachweisbar sind, bevor sich in anderen Untersuchungen Krankheitszeichen erkennen lassen.

[Near-infrared Fundus Autofluorescence: Clinical Application and Diagnostic Relevance]

Near-infrared autofluorescence (NIA) is a non-invasive retinal imaging technique for examination of the retinal pigment epithelium (RPE) based on the autofluorescence of melanin. Melanin has several functions within the RPE cells, in one of them it serves as a protective antioxidative factor within the RPE cells and is involved in the phagocytosis of photoreceptor outer segments. Disorders that affect the photoreceptor-RPE complex result in alterations of RPE cells which are detectable by alterations of NIA. Therefore, NIA allows to detect early alterations in inherited and acquired chorioretinal disorders, frequently prior to ophthalmoscopical visualisation and often prior to alterations in lipofuscin associated fundus autofluorescence (FAF) or optical coherence tomography (OCT). Although NIA and FAF relate to disorders affecting the RPE, findings between both imaging methods differ and the area involved has been demonstrated to be larger in NIA compared to FAF in several disorders (e.g., age-related macular degeneration, retinitis pigmentosa, ABCA4-gene associated Stargardt disease and cone-rod dystrophy, light damage), indicating that NIA detects earlier alterations compared to FAF. In addition, due to the absence of blue-light filtering which limits foveal visualisation in FAF, foveal alterations can be much better detected using NIA. A reduced subfoveal NIA intensity is the earliest sign of autosomal dominant BEST1-associated disease, when FAF and OCT are still normal. In other disorders, a normal subfoveal NIA intensity is associated with good visual acuity. This review summarizes the present knowledge on NIA and demonstrates biomarkers for various chorioretinal disorders.