Impact of Photoreceptor Loss on Retinal Circuitry.

IF 5 2区医学 Q1 NEUROSCIENCES

Annual Review of Vision Science Pub Date : 2021-09-15 DOI:10.1146/annurev-vision-100119-124713

Joo Yeun Lee, Rachel A Care, Luca Della Santina, Felice A Dunn

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引用次数: 8

Abstract

Our sense of sight relies on photoreceptors, which transduce photons into the nervous system's electrochemical interpretation of the visual world. These precious photoreceptors can be disrupted by disease, injury, and aging. Once photoreceptors start to die, but before blindness occurs, the remaining retinal circuitry can withstand, mask, or exacerbate the photoreceptor deficit and potentially be receptive to newfound therapies for vision restoration. To maximize the retina's receptivity to therapy, one must understand the conditions that influence the state of the remaining retina. In this review, we provide an overview of the retina's structure and function in health and disease. We analyze a collection of observations on photoreceptor disruption and generate a predictive model to identify parameters that influence the retina's response. Finally, we speculate on whether the retina, with its remarkable capacity to function over light levels spanning nine orders of magnitude, uses these same adaptational mechanisms to withstand and perhaps mask photoreceptor loss.

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光感受器丧失对视网膜回路的影响。

我们的视觉依赖于光感受器，它将光子传递到神经系统对视觉世界的电化学解释中。这些珍贵的光感受器会被疾病、损伤和衰老破坏。一旦光感受器开始死亡，但在失明发生之前，剩余的视网膜回路可以承受、掩盖或加剧光感受器的缺陷，并有可能接受新的视力恢复疗法。为了最大限度地提高视网膜对治疗的接受性，必须了解影响剩余视网膜状态的条件。在这篇综述中，我们提供视网膜的结构和功能在健康和疾病的概述。我们分析了一系列关于光感受器破坏的观察结果，并生成了一个预测模型，以确定影响视网膜反应的参数。最后，我们推测视网膜是否具有在跨越九个数量级的光水平上发挥作用的非凡能力，使用这些相同的适应机制来承受并可能掩盖光感受器的丧失。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Annual Review of Vision Science Medicine-Ophthalmology

CiteScore

11.10

自引率

1.70%

发文量

期刊介绍： The Annual Review of Vision Science reviews progress in the visual sciences, a cross-cutting set of disciplines which intersect psychology, neuroscience, computer science, cell biology and genetics, and clinical medicine. The journal covers a broad range of topics and techniques, including optics, retina, central visual processing, visual perception, eye movements, visual development, vision models, computer vision, and the mechanisms of visual disease, dysfunction, and sight restoration. The study of vision is central to progress in many areas of science, and this new journal will explore and expose the connections that link it to biology, behavior, computation, engineering, and medicine.