Increased core body temperature in astronauts during long-duration space missions

Alexander C. Stahn; Andreas Werner; Oliver Opatz; Martina A. Maggioni; Mathias Steinach; Victoria Weller Von Ahlefeld; Alan Moore; Brian E. Crucian; Scott M. Smith; Sara R. Zwart; Thomas Schlabs; Stefan Mendt; Tobias Trippel; Eberhard Koralewski; Jochim Koch; Alexander Choukèr; Günther Reitz; Peng Shang; Lothar Röcker; Karl A. Kirsch; Hanns Christian Gunga

doi:10.1038/s41598-017-15560-w

Increased core body temperature in astronauts during long-duration space missions

Alexander C. Stahn
, Andreas Werner
, Oliver Opatz
, Martina A. Maggioni
, Mathias Steinach
, Victoria Weller Von Ahlefeld
, Alan Moore
, Brian E. Crucian
, Scott M. Smith
, Sara R. Zwart
, Thomas Schlabs
, Stefan Mendt
, Tobias Trippel
, Eberhard Koralewski
, Jochim Koch
, Alexander Choukèr
, Günther Reitz
, Peng Shang
, Lothar Röcker
, Karl A. Kirsch

Hanns Christian Gunga

生命学院

Charité - Universitätsmedizin Berlin
University of Pennsylvania
German Air Force
University of Milan
Lamar University
NASA Johnson Space Center
University of Texas Medical Branch at Galveston
Charité – Universitätsmedizin Berlin
Draegerwerk AG & Co. KGaA
Ludwig Maximilian University of Munich
German Aerospace Center
Institute of Plasma Physics of the Czech Academy of Sciences

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91 引用（Scopus）

摘要

Humans' core body temperature (CBT) is strictly controlled within a narrow range. Various studies dealt with the impact of physical activity, clothing, and environmental factors on CBT regulation under terrestrial conditions. However, the effects of weightlessness on human thermoregulation are not well understood. Specifically, studies, investigating the effects of long-duration spaceflight on CBT at rest and during exercise are clearly lacking. We here show that during exercise CBT rises higher and faster in space than on Earth. Moreover, we observed for the first time a sustained increased astronauts' CBT also under resting conditions. This increase of about 1 °C developed gradually over 2.5 months and was associated with augmented concentrations of interleukin-1 receptor antagonist, a key anti-inflammatory protein. Since even minor increases in CBT can impair physical and cognitive performance, both findings have a considerable impact on astronauts' health and well-being during future long-term spaceflights. Moreover, our findings also pinpoint crucial physiological challenges for spacefaring civilizations, and raise questions about the assumption of a thermoregulatory set point in humans, and our evolutionary ability to adapt to climate changes on Earth.

源语言	英语
文章编号	16180
期刊	Scientific Reports
卷	7
期	1
DOI	https://doi.org/10.1038/s41598-017-15560-w
出版状态	已出版 - 1 12月 2017

联合国可持续发展目标

此成果有助于实现下列可持续发展目标：

可持续发展目标 3 良好健康与福祉

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10.1038/s41598-017-15560-w

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Stahn, A. C., Werner, A., Opatz, O., Maggioni, M. A., Steinach, M., Von Ahlefeld, V. W., Moore, A., Crucian, B. E., Smith, S. M., Zwart, S. R., Schlabs, T., Mendt, S., Trippel, T., Koralewski, E., Koch, J., Choukèr, A., Reitz, G., Shang, P., Röcker, L., ... Gunga, H. C. (2017). Increased core body temperature in astronauts during long-duration space missions. Scientific Reports, 7(1), 文章 16180. https://doi.org/10.1038/s41598-017-15560-w

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title = "Increased core body temperature in astronauts during long-duration space missions",

abstract = "Humans' core body temperature (CBT) is strictly controlled within a narrow range. Various studies dealt with the impact of physical activity, clothing, and environmental factors on CBT regulation under terrestrial conditions. However, the effects of weightlessness on human thermoregulation are not well understood. Specifically, studies, investigating the effects of long-duration spaceflight on CBT at rest and during exercise are clearly lacking. We here show that during exercise CBT rises higher and faster in space than on Earth. Moreover, we observed for the first time a sustained increased astronauts' CBT also under resting conditions. This increase of about 1 °C developed gradually over 2.5 months and was associated with augmented concentrations of interleukin-1 receptor antagonist, a key anti-inflammatory protein. Since even minor increases in CBT can impair physical and cognitive performance, both findings have a considerable impact on astronauts' health and well-being during future long-term spaceflights. Moreover, our findings also pinpoint crucial physiological challenges for spacefaring civilizations, and raise questions about the assumption of a thermoregulatory set point in humans, and our evolutionary ability to adapt to climate changes on Earth.",

author = "Stahn, \{Alexander C.\} and Andreas Werner and Oliver Opatz and Maggioni, \{Martina A.\} and Mathias Steinach and \{Von Ahlefeld\}, \{Victoria Weller\} and Alan Moore and Crucian, \{Brian E.\} and Smith, \{Scott M.\} and Zwart, \{Sara R.\} and Thomas Schlabs and Stefan Mendt and Tobias Trippel and Eberhard Koralewski and Jochim Koch and Alexander Chouk{\`e}r and G{\"u}nther Reitz and Peng Shang and Lothar R{\"o}cker and Kirsch, \{Karl A.\} and Gunga, \{Hanns Christian\}",

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Stahn, AC, Werner, A, Opatz, O, Maggioni, MA, Steinach, M, Von Ahlefeld, VW, Moore, A, Crucian, BE, Smith, SM, Zwart, SR, Schlabs, T, Mendt, S, Trippel, T, Koralewski, E, Koch, J, Choukèr, A, Reitz, G, Shang, P, Röcker, L, Kirsch, KA & Gunga, HC 2017, 'Increased core body temperature in astronauts during long-duration space missions', Scientific Reports, 卷 7, 号码 1, 16180. https://doi.org/10.1038/s41598-017-15560-w

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T1 - Increased core body temperature in astronauts during long-duration space missions

AU - Stahn, Alexander C.

AU - Werner, Andreas

AU - Opatz, Oliver

AU - Maggioni, Martina A.

AU - Steinach, Mathias

AU - Von Ahlefeld, Victoria Weller

AU - Moore, Alan

AU - Crucian, Brian E.

AU - Smith, Scott M.

AU - Zwart, Sara R.

AU - Schlabs, Thomas

AU - Mendt, Stefan

AU - Trippel, Tobias

AU - Koralewski, Eberhard

AU - Koch, Jochim

AU - Choukèr, Alexander

AU - Reitz, Günther

AU - Shang, Peng

AU - Röcker, Lothar

AU - Kirsch, Karl A.

AU - Gunga, Hanns Christian

PY - 2017/12/1

Y1 - 2017/12/1

N2 - Humans' core body temperature (CBT) is strictly controlled within a narrow range. Various studies dealt with the impact of physical activity, clothing, and environmental factors on CBT regulation under terrestrial conditions. However, the effects of weightlessness on human thermoregulation are not well understood. Specifically, studies, investigating the effects of long-duration spaceflight on CBT at rest and during exercise are clearly lacking. We here show that during exercise CBT rises higher and faster in space than on Earth. Moreover, we observed for the first time a sustained increased astronauts' CBT also under resting conditions. This increase of about 1 °C developed gradually over 2.5 months and was associated with augmented concentrations of interleukin-1 receptor antagonist, a key anti-inflammatory protein. Since even minor increases in CBT can impair physical and cognitive performance, both findings have a considerable impact on astronauts' health and well-being during future long-term spaceflights. Moreover, our findings also pinpoint crucial physiological challenges for spacefaring civilizations, and raise questions about the assumption of a thermoregulatory set point in humans, and our evolutionary ability to adapt to climate changes on Earth.

AB - Humans' core body temperature (CBT) is strictly controlled within a narrow range. Various studies dealt with the impact of physical activity, clothing, and environmental factors on CBT regulation under terrestrial conditions. However, the effects of weightlessness on human thermoregulation are not well understood. Specifically, studies, investigating the effects of long-duration spaceflight on CBT at rest and during exercise are clearly lacking. We here show that during exercise CBT rises higher and faster in space than on Earth. Moreover, we observed for the first time a sustained increased astronauts' CBT also under resting conditions. This increase of about 1 °C developed gradually over 2.5 months and was associated with augmented concentrations of interleukin-1 receptor antagonist, a key anti-inflammatory protein. Since even minor increases in CBT can impair physical and cognitive performance, both findings have a considerable impact on astronauts' health and well-being during future long-term spaceflights. Moreover, our findings also pinpoint crucial physiological challenges for spacefaring civilizations, and raise questions about the assumption of a thermoregulatory set point in humans, and our evolutionary ability to adapt to climate changes on Earth.

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U2 - 10.1038/s41598-017-15560-w

DO - 10.1038/s41598-017-15560-w

M3 - 文章

C2 - 29170507

AN - SCOPUS:85034846763

SN - 2045-2322

VL - 7

JO - Scientific Reports

JF - Scientific Reports

IS - 1

M1 - 16180

ER -

Increased core body temperature in astronauts during long-duration space missions

摘要

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