Sensorimotor adaptation of locomotor synergies to gravitational constraint.

IF 4.4 1区 物理与天体物理 Q1 MULTIDISCIPLINARY SCIENCES npj Microgravity Pub Date : 2024-01-11 DOI:10.1038/s41526-024-00350-2
Etienne Guillaud, Vincent Leconte, Emilie Doat, Dominique Guehl, Jean-René Cazalets
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Abstract

This study investigates the impact of gravity on lower limb muscle coordination during pedaling. It explores how pedaling behaviors, kinematics, and muscle activation patterns dynamically adapts to changes in gravity and resistance levels. The experiment was conducted in parabolic flights, simulating microgravity, hypergravity (1.8 g), and normogravity conditions. Participants pedaled on an ergometer with varying resistances. The goal was to identify potential changes in muscle synergies and activation strategies under different gravitational contexts. Results indicate that pedaling cadence adjusted naturally in response to both gravity and resistance changes. Cadence increased with higher gravity and decreased with higher resistance levels. Muscular activities were characterized by two synergies representing pull and push phases of pedaling. The timing of synergy activation was influenced by gravity, with a delay in activation observed in microgravity compared to other conditions. Despite these changes, the velocity profile of pedaling remained stable across gravity conditions. The findings strongly suggest that the CNS dynamically manages the shift in body weight by finely tuning muscular coordination, thereby ensuring the maintenance of a stable motor output. Furthermore, electromyography analysis suggest that neuromuscular discharge frequencies were not affected by gravity changes. This implies that the types of muscle fibers recruited during exercise in modified gravity are similar to those used in normogravity. This research has contributed to a better understanding of how the human locomotor system responds to varying gravitational conditions, shedding light on the potential mechanisms underlying astronauts' gait changes upon returning from space missions.

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运动协同对重力约束的感觉运动适应。
本研究调查了重力对踩踏时下肢肌肉协调的影响。它探讨了蹬踏行为、运动学和肌肉激活模式如何动态适应重力和阻力水平的变化。实验在抛物线飞行中进行,模拟了微重力、超重力(1.8 克)和常重力条件。参与者在不同阻力的测力计上踩踏。目的是确定在不同重力环境下肌肉协同作用和激活策略的潜在变化。结果表明,蹬踏速度会随着重力和阻力的变化而自然调整。重力越大,步频越高,阻力越大,步频越低。肌肉活动的特点是两种协同作用,分别代表踏板的拉和推阶段。协同作用的激活时间受重力影响,与其他条件相比,在微重力条件下的激活时间有所延迟。尽管存在这些变化,但在不同重力条件下,蹬踏的速度曲线保持稳定。研究结果有力地表明,中枢神经系统通过微调肌肉协调来动态地管理体重的变化,从而确保维持稳定的运动输出。此外,肌电图分析表明,神经肌肉放电频率不受重力变化的影响。这意味着,在改变重力条件下运动时所募集的肌肉纤维类型与正常重力条件下相似。这项研究有助于更好地了解人类运动系统如何对不同重力条件做出反应,从而揭示宇航员在执行太空任务返回后步态变化的潜在机制。
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来源期刊
npj Microgravity
npj Microgravity Physics and Astronomy-Physics and Astronomy (miscellaneous)
CiteScore
7.30
自引率
7.80%
发文量
50
审稿时长
9 weeks
期刊介绍: A new open access, online-only, multidisciplinary research journal, npj Microgravity is dedicated to publishing the most important scientific advances in the life sciences, physical sciences, and engineering fields that are facilitated by spaceflight and analogue platforms.
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