Functional and structural readouts for early detection of retinal involvement in multiple sclerosis.

IF 2.6 3区 医学 Q2 BEHAVIORAL SCIENCES
Khaldoon O Al-Nosairy, Alexander Duscha, Henrike Buhr, Antonia Lipp, Christiane Desel, Tobias Hegelmaier, Hagen Thieme, Aiden Haghikia, Michael B Hoffmann
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引用次数: 0

Abstract

Introduction: The retina, a window into the brain, allows for the investigation of many disease-associated inflammatory and neurodegenerative changes affecting the central nervous system (CNS). Multiple sclerosis (MS), an autoimmune disease targeting the CNS, typically impacts on the visual system including the retina. Hence, we aimed to establish innovative functional retinal measures of MS-related damage, e.g., spatially resolved non-invasive retinal electrophysiology, backed by established morphological retinal imaging markers, i.e., optical coherence tomography (OCT).

Methods: 20 healthy controls (HC) and 37 people with MS [17 without history of optic neuritis (NON) and 20 with (HON) history of optic neuritis] were included. In this work, we differentially assessed photoreceptor/bipolar cells (distal retina) and retinal ganglion cell (RGC, proximal retina) function besides structural assessment (OCT). We compared two multifocal electroretinography-based approaches, i.e., the multifocal pattern electroretinogram (mfPERG) and the multifocal electroretinogram to record photopic negative response (mfERG PhNR ). Structural assessment utilized peripapillary retinal nerve fiber layer thickness (pRNFL) and macular scans to calculate outer nuclear thickness (ONL) and macular ganglion cell inner plexiform layer thickness (GCIPL). One eye was randomly selected per subject.

Results: In NON, photoreceptor/bipolar cell layer had dysfunctional responses evidenced by reduced mfERG PhNR -N1 peak time of the summed response, but preserved structural integrity. Further, both NON and HON demonstrated abnormal RGC responses as evidenced by the photopic negative response of mfERG PhNR (mfPhNR) and mfPERG indices (P < 0.05). Structurally, only HON had thinned retina at the level of RGCs in the macula (GCIPL, P < 0.01) and the peripapillary area (pRNFL, P < 0.01). All three modalities showed good performance to differentiate MS-related damage from HC, 71-81% area under curve.

Conclusion: In conclusion, while structural damage was evident mainly for HON, functional measures were the only retinal read-outs of MS-related retinal damage that were independent of optic neuritis, observed for NON. These results indicate retinal MS-related inflammatory processes in the retina prior to optic neuritis. They highlight the importance of retinal electrophysiology in MS diagnostics and its potential as a sensitive biomarker for follow-up in innovative interventions.

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早期检测多发性硬化症视网膜受累的功能和结构读数。
视网膜是进入大脑的窗口,可以研究许多与疾病相关的炎症和影响中枢神经系统(CNS)的神经退行性改变。多发性硬化症(MS)是一种针对中枢神经系统的自身免疫性疾病,通常会影响包括视网膜在内的视觉系统。因此,我们的目标是建立创新的功能性视网膜ms相关损伤测量方法,例如,空间分辨非侵入性视网膜电生理,并以已建立的视网膜形态学成像标记为基础,即光学相干断层扫描(OCT)。方法:选取20例健康对照(HC)和37例MS患者[17例无视神经炎(NON)病史,20例有视神经炎(HON)病史]。在这项工作中,除了结构评估(OCT)外,我们还对感光细胞/双极细胞(远端视网膜)和视网膜神经节细胞(RGC,近端视网膜)的功能进行了差异评估。我们比较了两种基于多焦视网膜电图的方法,即多焦模式视网膜电图(mfPERG)和多焦视网膜电图记录光负反应(mfERG PhNR)。结构评估利用乳头周围视网膜神经纤维层厚度(pRNFL)和黄斑扫描计算外核厚度(ONL)和黄斑神经节细胞内丛状层厚度(GCIPL)。每个受试者随机选择一只眼睛。结果:在NON中,光感受器/双极细胞层反应功能失调,mfERG PhNR -N1峰时间减少,但结构完整。此外,NON和HON均表现出异常的RGC反应,mfERG PhNR (mfPhNR)和mfPERG指数的光负反应证明了这一点(P < 0.05)。在结构上,只有HON在黄斑区(GCIPL, P < 0.01)和乳头周围区(pRNFL, P < 0.01)的RGCs水平上出现视网膜变薄。三种方法均能很好地区分ms相关损伤和HC,曲线下面积为71-81%。结论:结论:虽然结构损伤主要出现在HON中,但在NON中观察到的ms相关视网膜损伤中,功能指标是唯一独立于视神经炎的视网膜读数。这些结果表明视网膜ms相关的炎症过程在视神经炎之前的视网膜。他们强调了视网膜电生理在多发性硬化症诊断中的重要性,以及它作为一种敏感的生物标志物在创新干预措施中的潜力。
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来源期刊
Frontiers in Integrative Neuroscience
Frontiers in Integrative Neuroscience Neuroscience-Cellular and Molecular Neuroscience
CiteScore
4.60
自引率
2.90%
发文量
148
审稿时长
14 weeks
期刊介绍: Frontiers in Integrative Neuroscience publishes rigorously peer-reviewed research that synthesizes multiple facets of brain structure and function, to better understand how multiple diverse functions are integrated to produce complex behaviors. Led by an outstanding Editorial Board of international experts, this multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide. Our goal is to publish research related to furthering the understanding of the integrative mechanisms underlying brain functioning across one or more interacting levels of neural organization. In most real life experiences, sensory inputs from several modalities converge and interact in a manner that influences perception and actions generating purposeful and social behaviors. The journal is therefore focused on the primary questions of how multiple sensory, cognitive and emotional processes merge to produce coordinated complex behavior. It is questions such as this that cannot be answered at a single level – an ion channel, a neuron or a synapse – that we wish to focus on. In Frontiers in Integrative Neuroscience we welcome in vitro or in vivo investigations across the molecular, cellular, and systems and behavioral level. Research in any species and at any stage of development and aging that are focused at understanding integration mechanisms underlying emergent properties of the brain and behavior are welcome.
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