Retinal Response to Light Exposure in BEST1-mutant Dogs Evaluated with Ultra-high Resolution OCT

Overview

Journal Vision Res

Specialty Ophthalmology

Date 2024 Mar 9

PMID 38460402

Authors

Vivian Wu

Malgorzata Swider

Alexander Sumaroka

Valerie L Dufour

Joseph E Vance

Tomas S Aleman

Gustavo D Aguirre

William A Beltran

Artur V Cideciyan

Affiliations

Soon will be listed here.

Abstract

Mutations in BEST1 cause an autosomal recessive disease in dogs where the earliest changes localize to the photoreceptor-RPE interface and show a retina-wide micro-detachment that is modulated by light exposure. The purpose of this study was to define the spatial and temporal details of the outer retina and its response to light with ultra-high resolution OCT across a range of ages and with different BEST1 mutations. Three retinal regions were selected in each eye: near the fovea-like area, near the optic nerve, both in the tapetal area, and inferior to the optic nerve in the non-tapetal area. The OS+ slab thickness was defined between the peak near the junction of inner and outer segments (IS/OS) and the transition between basal RPE, Bruch membrane, choriocapillaris and proximal tapetum (RPE/T). In wildtype (WT) dogs, two tapetal regions showed additional hyperscattering OCT peaks within the OS+ slab likely representing cone and rod outer segment tips (COST and ROST). The inferior non-tapetal region of WT dogs had only one of these peaks, likely ROST. In dogs with BEST1 mutations, all three locations showed a single peak, likely suggesting optical silence of COST. Light-dependent expansion of the micro-detachment by about 10 um was detectable in both tapetal and non-tapetal retina across all ages and BEST1 mutations.

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