Monitoring Tissue Oxygen Saturation in Microgravity on Parabolic Flights

Gravitational and space research : publication of the American Society for Gravitational and Space Research Pub Date : 2016-12-01 DOI:10.2478/gsr-2016-0007

Thomas G. Smith, F. Formenti, P. Hodkinson, M. Khpal, Brian. Mackenwells, N. Talbot

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引用次数: 2

Abstract

Abstract Future spacecraft and crew habitats are anticipated to use a moderately hypobaric and hypoxic cabin atmosphere to reduce the risk of decompression sickness associated with extravehicular activity. This has raised concerns about potential hypoxia-mediated adverse effects on astronauts. Noninvasive technology for measuring tissue oxygen saturation (StO2) has been developed for clinical use and may be helpful in monitoring oxygenation during spaceflight. We conducted a technical evaluation of a handheld StO2 monitor during a series of parabolic flights, and then undertook a preliminary analysis of the data obtained during the flights from six individuals. The StO2 monitor operated normally in all gravity conditions. There was considerable variability in StO2 between and within individuals. Overall, transition to microgravity was associated with a small decrease in StO2 of 1.1±0.3%. This evaluation has established the basic function of this technology in microgravity and demonstrates the potential for exploring its use in space.

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在微重力抛物线飞行中监测组织氧饱和度

未来的航天器和乘员栖息地预计将使用适度的低压和低氧舱内气氛，以降低与舱外活动相关的减压病的风险。这引起了人们对缺氧对宇航员潜在不利影响的担忧。用于测量组织氧饱和度(StO2)的无创技术已被开发用于临床应用，并可能有助于监测航天飞行中的氧合。我们在一系列抛物线飞行中对手持式StO2监测器进行了技术评估，然后对六个人在飞行过程中获得的数据进行了初步分析。StO2监测器在所有重力条件下工作正常。个体之间和个体内部的StO2存在相当大的差异。总体而言，过渡到微重力与StO2小幅下降(1.1±0.3%)有关。这项评价确定了这项技术在微重力条件下的基本功能，并显示了探索其在空间应用的潜力。

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

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