Impact of microgravity on retinal neuroimmune responses and visual dysfunction in rats.

IF 1.8 4区医学 Q2 OPHTHALMOLOGY

International journal of ophthalmology Pub Date : 2025-08-18 eCollection Date: 2025-01-01 DOI:10.18240/ijo.2025.08.01

Jin-Shuo Liu, Nai-Qin Yan, Ying-Yan Mao, Chen Xin, Da-Peng Mou, Xin-Xiao Gao, Jia Guo, Ning-Li Wang, Si-Quan Zhu

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引用次数: 0

Abstract

Aim: To analyze visual dysfunction in rats under simulated weightlessness (SW) by examining trans-laminar cribrosa pressure difference (TLCPD) and neuroimmune responses.

Methods: The 72 male Sprague-Dawley rats were randomly assigned into two groups (ground control and hindlimb unloading-simulated microgravity) using stratified randomization, with each group further subdivided into three exposure durations: SW 2-week (SW-2W), 4-week (SW-4W), and 8-week (SW-8W), n=12 per subgroup. At the designated time points for each group, intraocular pressure (IOP) and intracranial pressure (ICP) were measured, and the trans-laminar cribrosa pressure difference (TLCPD) was calculated. Additionally, optomotor response (OMR), electroretinography (ERG), and optical coherence tomography (OCT) were performed. The number of retinal ganglion cells (RGCs) was quantified via immunofluorescence, the activation of astrocytes and microglial cells was determined, and Sholl analysis was conducted to assess the function and morphology of microglial cells. Data were analyzed with SPSS and GraphPad Prism (P<0.05).

Results: Under prolonged simulated microgravity, rats exhibited a progressive increase in both IOP and ICP, with the most pronounced rise observed at 8wk. Concurrently, the TLCPD shifted from a negative value in controls to a positive value. These pressure alterations were associated with retinal dysfunction, as evidenced by significant reductions in ERG b-wave and photopic negative response (PhNR) amplitudes. OCT and histological analyses revealed subtle photoreceptor layer damage: while the inner nuclear layer (INL) thickness remained relatively unchanged, the outer nuclear layer (ONL) thinned significantly, and the nerve fiber layer-ganglion cell layer complex thickness (NFL-GCL) complex initially thickened before later thinning. Immunofluorescence further demonstrated marked neuroimmune activation, with astrocytes transitioning from having large cell bodies with small, elongated, sparse processes to a phenotype characterized by compact, enlarged nuclei and aggregated processes, alongside notable RGC loss.

Conclusion: Based on the results from the simulated microgravity rat model, microgravity-induced changes in dual-chamber pressure, and neuroimmune responses in the retina may play a key role in visual dysfunction. Specifically, the activation of retinal neuroimmune cells (astrocytes and microglial cells) induced by mechanical stress appears to be central to retinal and optic nerve damage.

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微重力对大鼠视网膜神经免疫反应和视觉功能障碍的影响。

目的：通过观察网膜压差（TLCPD）和神经免疫反应，分析模拟失重状态下大鼠的视觉功能障碍。方法：将72只雄性sd大鼠随机分为地面对照组和模拟后肢卸载微重力组，每组再细分为SW 2周（SW- 2w）、4周（SW- 4w）和8周（SW- 8w） 3个暴露时间，每亚组n=12只。各组在指定时间点测量眼内压（IOP）、颅内压（ICP），计算板间压差（TLCPD）。此外，还进行了视运动反应（OMR）、视网膜电图（ERG）和光学相干断层扫描（OCT）。采用免疫荧光法定量视网膜神经节细胞（RGCs）数量，测定星形胶质细胞和小胶质细胞的活化情况，采用Sholl分析法评价小胶质细胞的功能和形态。结果：在长时间模拟微重力作用下，大鼠IOP和ICP均呈进行性升高，在8周时升高最为明显。同时，TLCPD从控制组的负值变为正值。这些压力变化与视网膜功能障碍有关，ERG b波和光负反应（PhNR）振幅的显著降低证明了这一点。OCT和组织学分析显示光感器层有轻微损伤：内核层（INL）厚度保持相对不变，外核层（ONL）明显变薄，神经纤维层-神经节细胞层复合体厚度（NFL-GCL）复合体先增厚后变薄。免疫荧光进一步显示了显著的神经免疫激活，星形胶质细胞从具有大细胞体和小、细长、稀疏的突起转变为具有致密、增大的细胞核和聚集突起的表型，同时伴有显著的RGC丢失。结论：基于模拟微重力大鼠模型的结果，微重力诱导的双腔压力变化和视网膜神经免疫反应可能在视觉功能障碍中起关键作用。具体来说，机械应力诱导的视网膜神经免疫细胞（星形胶质细胞和小胶质细胞）的激活似乎是视网膜和视神经损伤的核心。

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

International journal of ophthalmology Medicine-Ophthalmology

CiteScore

2.50

自引率

7.10%

发文量

3141

审稿时长

4-8 weeks

期刊介绍： · International Journal of Ophthalmology-IJO (English edition) is a global ophthalmological scientific publication and a peer-reviewed open access periodical (ISSN 2222-3959 print, ISSN 2227-4898 online). This journal is sponsored by Chinese Medical Association Xi’an Branch and obtains guidance and support from WHO and ICO (International Council of Ophthalmology). It has been indexed in SCIE, PubMed, PubMed-Central, Chemical Abstracts, Scopus, EMBASE , and DOAJ. IJO JCR IF in 2017 is 1.166. IJO was established in 2008, with editorial office in Xi’an, China. It is a monthly publication. General Scientific Advisors include Prof. Hugh Taylor (President of ICO); Prof.Bruce Spivey (Immediate Past President of ICO); Prof.Mark Tso (Ex-Vice President of ICO) and Prof.Daiming Fan (Academician and Vice President, Chinese Academy of Engineering. International Scientific Advisors include Prof. Serge Resnikoff (WHO Senior Speciatist for Prevention of blindness), Prof. Chi-Chao Chan (National Eye Institute, USA) and Prof. Richard L Abbott (Ex-President of AAO/PAAO) et al. Honorary Editors-in-Chief: Prof. Li-Xin Xie(Academician of Chinese Academy of Engineering/Honorary President of Chinese Ophthalmological Society); Prof. Dennis Lam (President of APAO) and Prof. Xiao-Xin Li (Ex-President of Chinese Ophthalmological Society). Chief Editor: Prof. Xiu-Wen Hu (President of IJO Press). Editors-in-Chief: Prof. Yan-Nian Hui (Ex-Director, Eye Institute of Chinese PLA) and Prof. George Chiou (Founding chief editor of Journal of Ocular Pharmacology & Therapeutics). Associate Editors-in-Chief include: Prof. Ning-Li Wang (President Elect of APAO); Prof. Ke Yao (President of Chinese Ophthalmological Society) ; Prof.William Smiddy (Bascom Palmer Eye instituteUSA) ; Prof.Joel Schuman (President of Association of University Professors of Ophthalmology,USA); Prof.Yizhi Liu (Vice President of Chinese Ophtlalmology Society); Prof.Yu-Sheng Wang (Director of Eye Institute of Chinese PLA); Prof.Ling-Yun Cheng (Director of Ocular Pharmacology, Shiley Eye Center, USA). IJO accepts contributions in English from all over the world. It includes mainly original articles and review articles, both basic and clinical papers. Instruction is Welcome Contribution is Welcome Citation is Welcome Cooperation organization International Council of Ophthalmology(ICO), PubMed, PMC, American Academy of Ophthalmology, Asia-Pacific, Thomson Reuters, The Charlesworth Group, Crossref,Scopus,Publons, DOAJ etc.