The effect of spaceflight on the otolith-mediated ocular counter-roll

4th Symposium on Space Educational Activities Pub Date : 2022-04-01 DOI:10.5821/conference-9788419184405.122

Catho Schoenmaekers, Chloé De Laet, L. Kornilova, D. Glukhikh, S. Moore, H. MacDougall, I. Naumov, Erik Fransén, Leander Wille, S. Jillings, F. Wuyts

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Abstract

The otoliths of the vestibular system are seen as the primary gravitational sensors and are responsible for a compensatory eye torsion called the ocular counter-roll (OCR). The OCR ensures gaze stabilization and is sensitive to a lateral head roll with respect to gravity and the Gravito-Inertial Acceleration (GIA) vector during e.g., centrifugation. This otolith-mediated reflex will make sure you will still be able to maintain gaze stabilization and postural stability when making sharp turns during locomotion. To measure the effect of prolonged spaceflight on the otoliths, we measured the OCR induced by off-axis centrifugation in a group of 27 cosmonauts before and after their 6-month space mission to the International Space Station (ISS). We observed a significant decrease in OCR early post-flight, with first- time flyers being more strongly affected compared to frequent or experienced flyers. Our results strongly suggest that experienced space crew have acquired the ability to adapt faster after G-transitions and should therefore be sent for more challenging space missions, e.g., Moon or Mars, because they are noticeably less affected by microgravity regarding their vestibular system.

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航天飞行对耳石介导的眼反滚的影响

前庭系统的耳石被视为主要的重力传感器，负责代偿性眼扭转，称为眼反转(OCR)。OCR确保凝视稳定，并且对横向头部滚动相对于重力和重力惯性加速度(GIA)矢量敏感，例如在离心过程中。这种耳石介导的反射将确保你在运动中做急转弯时仍然能够保持凝视稳定和姿势稳定。为了测量长时间太空飞行对耳石的影响，我们测量了27名宇航员在前往国际空间站(ISS)执行为期6个月的太空任务之前和之后的离轴离心引起的耳石OCR。我们观察到飞行后早期OCR显著下降，与频繁或有经验的飞行者相比，第一次飞行的人受到的影响更大。我们的研究结果强烈表明，经验丰富的宇航员已经获得了在g转换后更快适应的能力，因此应该被送往更具挑战性的太空任务，例如月球或火星，因为他们的前庭系统明显较少受到微重力的影响。

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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4th Symposium on Space Educational Activities

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