在较低温度下进行浸入式递增运动时，最大工作量会降低，但峰值摄氧量不会降低。

Maximal workload but not peak oxygen uptake is decreased during immersed incremental exercise at cooler temperatures.

作者信息

Fujimoto Tomomi, Sasaki Yosuke, Wakabayashi Hitoshi, Sengoku Yasuo, Tsubakimoto Shozo, Nishiyasu Takeshi

机构信息

Institute of Health and Sport Sciences, University of Tsukuba, Tsukuba, Ibaraki, 305-8574, Japan.

Division of Human Environmental Systems, Faculty of Engineering, Hokkaido University, Hokkaido, Japan.

出版信息

Eur J Appl Physiol. 2016 Sep;116(9):1819-27. doi: 10.1007/s00421-016-3438-3. Epub 2016 Jul 25.

DOI:10.1007/s00421-016-3438-3

PMID:27456478

Abstract

PURPOSE

This study investigated the effects of water temperature on cardiorespiratory responses and exercise performance during immersed incremental cycle exercise until exhaustion.

METHODS

Ten healthy young men performed incremental cycle exercise on a water cycle ergometer at water temperatures (T w) of 18, 26 and 34 °C. Workload was initially set at 60 W and was increased by 20 W every 2 min for the first four levels and then by 10 W every minute until the subject could no longer continue.

RESULTS

During submaximal exercise (60-120 W), [Formula: see text] was greater at T w = 18 °C than at 26 or 34 °C. Maximal workload was lower at T w = 18 °C than at 26 or 34 °C [T w = 18 °C: 138 ± 16 (SD) W, T w = 26 °C: 157 ± 16 W, T w = 34 °C: 156 ± 18 W], whereas [Formula: see text]O2peak did not differ among the three temperatures [T w = 18 °C: 3156 ± 364 (SD) ml min(-1), T w = 26 °C: 3270 ± 344 ml min(-1), T w = 34 °C: 3281 ± 268 ml min(-1)]. Minute ventilation ([Formula: see text]) and tidal volume (V T) during submaximal exercise were higher at T w = 18 °C than at 26 or 34 °C, while respiratory frequency (f R) did not differ with respect to T w.

CONCLUSION

Peak workload during immersed incremental cycle exercise is lower in cold water (18 °C) due to the higher [Formula: see text] during submaximal exercise, while the greater [Formula: see text] in cold water was due to a larger V T.

摘要

目的

本研究调查了水温对沉浸式递增循环运动直至力竭期间心肺反应和运动表现的影响。

方法

10名健康年轻男性在水温（Tw）分别为18、26和34°C的水上自行车测力计上进行递增循环运动。工作量最初设定为60W，在前四个水平中每2分钟增加20W，然后每分钟增加10W，直至受试者无法继续。

结果

在次最大运动（60 - 120W）期间，Tw = 18°C时的[公式：见原文]高于26或34°C时。Tw = 18°C时的最大工作量低于26或34°C时[Tw = 18°C：138 ± 16（标准差）W，Tw = 26°C：157 ± 16W，Tw = 34°C：156 ± 18W]，而三种温度下的[公式：见原文]O2峰值无差异[Tw = 18°C：3156 ± 364（标准差）ml min(-1)，Tw = 26°C：3270 ± 344 ml min(-1)，Tw = 34°C：3281 ± 268 ml min(-1)]。次最大运动期间的分钟通气量（[公式：见原文]）和潮气量（VT）在Tw = 18°C时高于26或34°C时，而呼吸频率（fR）在不同水温下无差异。

结论

由于次最大运动期间较高的[公式：见原文]，冷水（18°C）中沉浸式递增循环运动的峰值工作量较低，而冷水中较大的[公式：见原文]是由于较大的VT。

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在较低温度下进行浸入式递增运动时，最大工作量会降低，但峰值摄氧量不会降低。

Maximal workload but not peak oxygen uptake is decreased during immersed incremental exercise at cooler temperatures.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

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方法

结果

结论

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