Does Long-Duration Exposure to Microgravity Lead to Dysregulation of the Brain and Ocular Glymphatic Systems?

IF 3.1 Q1 OPHTHALMOLOGY

Eye and Brain Pub Date : 2022-05-01 DOI:10.2147/EB.S354710

P. Wostyn, T. Mader, C. Gibson, M. Nedergaard

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引用次数: 4

Abstract

Abstract Spaceflight-associated neuro-ocular syndrome (SANS) has been well documented in astronauts both during and after long-duration spaceflight and is characterized by the development of optic disc edema, globe flattening, choroidal folds, and hyperopic refractive error shifts. The exact mechanisms underlying these ophthalmic abnormalities remain unclear. New findings regarding spaceflight-associated alterations in cerebrospinal fluid spaces, specifically perivascular spaces, may shed more light on the pathophysiology of SANS. The preliminary results of a recent brain magnetic resonance imaging study show that perivascular spaces enlarge under prolonged microgravity conditions, and that the amount of fluid in perivascular spaces is linked to SANS. The exact pathophysiological mechanisms underlying enlargement of perivascular spaces in space crews are currently unclear. Here, we speculate that the dilation of perivascular spaces observed in long-duration space travelers may result from impaired cerebral venous outflow and compromised cerebrospinal fluid resorption, leading to obstruction of glymphatic perivenous outflow and increased periarterial cerebrospinal fluid inflow, respectively. Further, we provide a possible explanation for how dilated perivascular spaces can be associated with SANS. Given that enlarged perivascular spaces in space crews may be a marker of altered venous hemodynamics and reduced cerebrospinal fluid outflow, at the level of the optic nerve and eye, these disturbances may contribute to SANS. If confirmed by further studies, brain glymphatic dysfunction in space crews could potentially be considered a risk factor for the development of neurodegenerative diseases, such as Alzheimer’s disease. Furthermore, long-duration exposure to microgravity might contribute to SANS through dysregulation of the ocular glymphatic system. If prolonged spaceflight exposure causes disruption of the glymphatic systems, this might affect the ability to conduct future exploration missions, for example, to Mars. The considerations outlined in the present paper further stress the crucial need to develop effective long-term countermeasures to mitigate SANS-related physiologic changes during long-duration spaceflight.

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长时间暴露在微重力环境下会导致脑和眼淋巴系统失调吗?

摘要太空飞行相关的神经眼综合征（SANS）在宇航员长期太空飞行期间和之后都有很好的记录，其特征是视盘水肿、眼球扁平、脉络膜折叠和远视屈光不正移位。这些眼科异常的确切机制尚不清楚。关于太空飞行相关脑脊液空间，特别是血管周围空间改变的新发现，可能会为SANS的病理生理学提供更多的线索。最近一项脑磁共振成像研究的初步结果表明，在长时间的微重力条件下，血管周围空间会扩大，并且血管周围空间中的液体量与SANS有关。太空工作人员血管周围间隙扩大的确切病理生理机制目前尚不清楚。在此，我们推测，在长期太空旅行者中观察到的血管周围空间扩张可能是由于脑静脉流出受损和脑脊液吸收受损，分别导致淋巴管周围静脉流出受阻和动脉周围脑脊液流入增加。此外，我们为扩张的血管周围间隙如何与SANS相关提供了可能的解释。鉴于太空工作人员血管周围空间增大可能是视神经和眼睛水平静脉血流动力学改变和脑脊液流出减少的标志，这些干扰可能导致SANS。如果得到进一步研究的证实，太空工作人员的大脑交感神经功能障碍可能被认为是神经退行性疾病（如阿尔茨海默病）发展的风险因素。此外，长期暴露在微重力环境中可能会导致眼部免疫系统失调，从而导致SANS。如果长时间的太空飞行暴露导致glymphatic系统中断，这可能会影响未来执行探测任务的能力，例如火星探测任务。本文中概述的考虑因素进一步强调，迫切需要制定有效的长期对策，以缓解长期太空飞行中与SANS相关的生理变化。

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

Eye and Brain OPHTHALMOLOGY-

CiteScore

7.90

自引率

2.30%

发文量

审稿时长

16 weeks

期刊介绍： Eye and Brain is an international, peer-reviewed, open access journal focusing on basic research, clinical findings, and expert reviews in the field of visual science and neuro-ophthalmology. The journal’s unique focus is the link between two well-known visual centres, the eye and the brain, with an emphasis on the importance of such connections. All aspects of clinical and especially basic research on the visual system are addressed within the journal as well as significant future directions in vision research and therapeutic measures. This unique journal focuses on neurological aspects of vision – both physiological and pathological. The scope of the journal spans from the cornea to the associational visual cortex and all the visual centers in between. Topics range from basic biological mechanisms to therapeutic treatment, from simple organisms to humans, and utilizing techniques from molecular biology to behavior. The journal especially welcomes primary research articles or review papers that make the connection between the eye and the brain. Specific areas covered in the journal include: Physiology and pathophysiology of visual centers, Eye movement disorders and strabismus, Cellular, biochemical, and molecular features of the visual system, Structural and functional organization of the eye and of the visual cortex, Metabolic demands of the visual system, Diseases and disorders with neuro-ophthalmic manifestations, Clinical and experimental neuro-ophthalmology and visual system pathologies, Epidemiological studies.