Abating Heat Accrual During Exercise in Microgravity and Implications for Future Long-Term Missions.

IF 0.9 4区医学 Q4 BIOPHYSICS Aerospace medicine and human performance Pub Date : 2025-01-01 DOI:10.3357/AMHP.6536.2024

Katherine Maguire, Margaret Wydotis, Lance Bollinger, John Caruso

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Abstract

Introduction: Space agencies will embark on manned journeys to Mars on smaller vehicles than those used previously. In-flight exercise on those flights must abate the adverse effects microgravity (μG) has on humans. Due to space constraints on these vehicles, a single exercise device must address multiple fitness needs. Exercise and μG individually cause body heat accrual. During in-flight exercise they conspire to exacerbate heat gain. Given the duration of Mars missions and volume of exercise they entail, excess heat accrual must be addressed.

Methods: This review presents data on μG, thermoregulation, and exercise. Since their relationships are impacted by other variables, energy balance, body water, and cerebral and vascular physiology are discussed. Data are integrated to acknowledge the challenges long-term missions, and the in-flight exercise that accompanies them, impose on thermoregulation. Strategies to limit heat accrual are discussed.

Results: Current in-flight exercise and hardware will not address heat accrual mitigation or operational performance needs for Mars missions.

Discussion: This review suggests for future missions, crewmembers: 1) consume beverages with high sodium contents; 2) employ palm cooling for conductive heat transfer; and 3) perform plyometric exercise on gravity-independent hardware. Research should continue to evaluate these treatments to abate heat gain in μG. Maguire K, Wydotis M, Bollinger L, Caruso J. Abating heat accrual during exercise in microgravity and implications for future long-term missions. Aerosp Med Hum Perform. 2025; 96(1):53-61.

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减少在微重力下运动时产生的热量及其对未来长期任务的影响。

太空机构将开始载人火星之旅，使用比以前更小的飞行器。这些飞行中的飞行锻炼必须减轻微重力对人类的不利影响。由于这些交通工具的空间限制，单个运动设备必须满足多种健身需求。运动和μG都能引起身体热量的积累。在飞行中锻炼时，它们会共同加剧热量的增加。考虑到火星任务的持续时间和运动量，必须解决热量积累过剩的问题。方法：本文综述了有关μG、体温调节和运动的数据。由于它们的关系受到其他变量的影响，因此本文讨论了能量平衡、体内水分和脑血管生理学。数据被整合起来，以确认长期任务以及伴随飞行的飞行训练对体温调节的挑战。讨论了限制热积累的策略。结果：目前的飞行演习和硬件将无法解决火星任务的热量累积缓解或操作性能需求。讨论：这篇综述建议，对于未来的任务，机组人员：1)饮用高钠含量的饮料；2)采用手掌冷却进行导热；3)在不依赖重力的硬件上进行增强运动。研究应继续评估这些治疗方法，以减少μG中的热量增加。马奎尔，维多提斯M，波林杰L，卡鲁索J.减少微重力运动中热量积累及其对未来长期任务的影响。航空航天Med Hum Perform. 2025；96(1): 53 - 61。

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来源期刊

Aerospace medicine and human performance PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH -MEDICINE, GENERAL & INTERNAL

CiteScore

1.10

自引率

22.20%

发文量

272

期刊介绍： The peer-reviewed monthly journal, Aerospace Medicine and Human Performance (AMHP), formerly Aviation, Space, and Environmental Medicine, provides contact with physicians, life scientists, bioengineers, and medical specialists working in both basic medical research and in its clinical applications. It is the most used and cited journal in its field. It is distributed to more than 80 nations.

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