Advanced computational model of rod ERG kinetics.

IF 2.6 4区 医学 Q2 OPHTHALMOLOGY
Documenta Ophthalmologica Pub Date : 2024-08-01 Epub Date: 2024-07-03 DOI:10.1007/s10633-024-09977-8
Christopher W Tyler
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引用次数: 0

Abstract

Purpose: The electroretinogram (ERG) is the summed response from all levels of the retinal processing of light, and exhibits several profound nonlinearities in the underlying processing pathways. Accurate computational models of the ERG are important, both for understanding the multifold processes of light transduction to ecologically useful signals by the retina, and for their diagnostic capabilities for the identification and characterization of retinal disease mechanisms. There are, however, very few computational models of the ERG waveform, and none that account for the full extent of its features over time.

Methods: This study takes the neuroanalytic approach to modeling the ERG waveform, defined as a computational model based on the main features of the transmitter kinetics of the retinal neurons.

Results: The present neuroanalytic model of the human rod ERG is elaborated from the same general principles as that of Hood and Birch (Vis Neurosci 8(2):107-126, 1992), but incorporates the more recent understanding of the early nonlinear stages of ERG generation by Robson and Frishman (Prog Retinal Eye Res 39:1-22, 2014). As a result, it provides a substantially better match than previous models of rod responses in six different waveform features of the ERG flash intensity series on which the Hood and Birch model was based.

Conclusion: The neuroanalytic approach extends previous models of the component waves of the ERG, and can be structured to provide an accurate characterization of the full timecourse of the ERG waveform. The approach thus holds promise for advancing the theoretical understanding of the retinal kinetics of the light response.

Abstract Image

杆状 ERG 动力学高级计算模型。
目的:视网膜电图(ERG)是视网膜处理光的各级反应的总和,在底层处理途径中表现出若干深刻的非线性。精确的视网膜电图(ERG)计算模型非常重要,它既能帮助理解视网膜将光传导为生态有用信号的多重过程,又能帮助识别和描述视网膜疾病机制的诊断能力。然而,目前关于 ERG 波形的计算模型非常少,而且没有一个模型能解释 ERG 随时间变化的全部特征:本研究采用神经分析方法建立 ERG 波形模型,即根据视网膜神经元递质动力学的主要特征建立计算模型:本人类视杆细胞ERG神经分析模型与胡德和伯奇(Vis Neurosci 8(2):107-126,1992)的一般原理相同,但结合了罗布森和弗里什曼(Prog Retinal Eye Res 39:1-22,2014)对ERG产生早期非线性阶段的最新理解。因此,与之前的ERG闪光强度序列中六种不同波形特征的杆状反应模型相比,该模型提供了更好的匹配,而胡德和伯奇的模型正是建立在这六种不同波形特征的基础之上:结论:神经分析方法扩展了以前的 ERG 成分波模型,并能对 ERG 波形的整个时间过程进行准确描述。因此,这种方法有望推进对视网膜光反应动力学的理论理解。
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
Documenta Ophthalmologica
Documenta Ophthalmologica 医学-眼科学
CiteScore
3.50
自引率
21.40%
发文量
46
审稿时长
>12 weeks
期刊介绍: Documenta Ophthalmologica is an official publication of the International Society for Clinical Electrophysiology of Vision. The purpose of the journal is to promote the understanding and application of clinical electrophysiology of vision. Documenta Ophthalmologica will publish reviews, research articles, technical notes, brief reports and case studies which inform the readers about basic and clinical sciences related to visual electrodiagnosis and means to improve diagnosis and clinical management of patients using visual electrophysiology. Studies may involve animals or humans. In either case appropriate care must be taken to follow the Declaration of Helsinki for human subject or appropriate humane standards of animal care (e.g., the ARVO standards on Animal Care and Use).
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