Physiological Effects of Spaceflight/Unloading and the Mitigating Effects of Flywheel-Based Resistive Exercise

Gravitational and space research : publication of the American Society for Gravitational and Space Research Pub Date : 2016-07-01 DOI:10.2478/gsr-2016-0006

Prashant J. Parmar, R. Perry, Greta M. Cesarz, Alex Roberts, Houston Hardman, J. Caruso

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Abstract

Abstract The deleterious effects of spaceflight encompass numerous physiological effects that undermine long-term goals of manned round-trip missions to Mars. Among the greater losses are to the human musculoskeletal system due to limited mechanical/load-bearing activity. In-flight exercise and nutritional countermeasures seek to reduce physiological losses. Restoration of mechanical/load-bearing activity in microgravity is achieved with flywheel-based exercise hardware. Research with spaceflight analogs showed exercise done with flywheel-based devices abated muscle mass and strength losses with modest increases in net energy costs. This led to the installment of flywheel-based hardware on The International Space Station (ISS). To date, exercise with flywheel-based hardware has reduced musculoskeletal losses, with more success achieved for muscle-, versus bone-based, outcomes. In-flight exercise may better address bone losses with hardware that imparts high rates of impulse loading to the engaged musculoskeleton.

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航天/卸载的生理效应和基于飞轮的阻力运动的缓解效应

太空飞行的有害影响包括许多生理影响，这些影响破坏了载人火星往返任务的长期目标。其中较大的损失是由于有限的机械/承重活动对人体肌肉骨骼系统造成的。飞行中的锻炼和营养对策旨在减少生理损失。在微重力环境下，机械/承重活动的恢复是通过基于飞轮的运动硬件实现的。航天模拟研究表明，用飞轮装置进行的锻炼减少了肌肉质量和力量损失，同时净能量消耗适度增加。这导致了在国际空间站(ISS)上安装基于飞轮的硬件。迄今为止，以飞轮为基础的运动已经减少了肌肉骨骼的损失，与以骨骼为基础的运动相比，以肌肉为基础的运动取得了更大的成功。飞行中锻炼可以更好地解决骨质流失问题，因为硬件可以给参与的肌肉骨骼带来高速率的脉冲负荷。

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Gravitational and space research : publication of the American Society for Gravitational and Space Research

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