Air speed and direction affect metabolic and thermoregulatory responses during walking and running in a temperate environment.

IF 3.3 3区医学 Q1 PHYSIOLOGY

Journal of applied physiology Pub Date : 2024-09-01 Epub Date: 2024-06-13 DOI:10.1152/japplphysiol.00159.2024

Naoyuki Yamashita, Cynthia L Ly, James W Smallcombe, Simon Hodder, George Havenith

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引用次数: 0

Abstract

Revisiting classical experiments on the impact of air resistance on metabolic rate, we aimed to overcome limitations of previous research, notably: low participant numbers (n = 1-3), highly turbulent wind, and confounding effects of rising body temperature. In a custom-built wind tunnel with reduced turbulence, 14 participants (8 males, 6 females) walked (5 km·h^-1) and ran on a treadmill (70%V̇o_2max) at 0, 2, 4, and 6 m·s^-1 headwind or tailwind in a counterbalanced design, with rest breaks between each exposure to avoid rises in body core temperature. Oxygen consumption (V̇o₂) exhibited strong linear relationships versus wind direction, dynamic pressure, and air speed squared (V_wr²), lower in magnitude for headwind than tailwind. A moderate linear relationship was observed between heart rate, wind direction, dynamic pressure, and V_wr². Below 4 m·s^-1, the effect of wind was well within inter- and intraindividual variation and equipment uncertainty, and only at wind speeds ≥4 m·s^-1 did the differences in physiological responses reach statistical significance. Our data indicate that at running speeds below 4 m·s^-1 (14.4 km/h), indoor treadmills and outdoor running are comparable in terms of the metabolic impact of air movement relative to the person. However, this does not extend to the thermoregulatory effect of wind, with outdoor running providing a higher cooling rate due to the self-generated wind created during running. By removing the confounding impact of core temperature rises, the observed effects of headwind were lower and those of tailwind larger than observed previously. In the context of middle-distance running, the headwind created by running at 21.5 km·h^-1 would result in a 2.2% increase of V̇o₂. A relative tailwind of the same speed would lead to a 3.1% reduction.NEW & NOTEWORTHY Revisiting classical work by Pugh and Davies on the metabolic effects of air speed and direction, shortcomings in the original studies were addressed. Using more participants, less turbulent wind, and avoiding confounding effects of work-induced core temperature increases, new equations describing the impact of air speed/direction were developed. This study observed a lower impact of headwind and a larger impact of tailwind in the absence of an exercise-induced core temperature increase.

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气流速度和方向会影响在温带环境中步行和跑步时的新陈代谢和体温调节反应。

我们重温了空气阻力对新陈代谢率影响的经典实验，旨在克服以往研究的局限性，尤其是：参与人数少（n=1-3）、风力湍急以及体温升高的干扰效应。在一个定制的减少湍流的风洞中，14 名参与者（8 名男性，6 名女性）在跑步机上以 0、2、4 和 6 m.s-1 的逆风或顺风行走（5 km.h-1）和跑步（70%V̇O2max），每次暴露之间都有休息时间，以避免身体核心温度升高。耗氧量（V.J.O.2）与风向、动压和气速平方（Vwr2）呈很强的线性关系，顺风时的数值低于逆风时。心率、风向、动压和 Vwr2 之间呈中度线性关系。风速低于 4 米⸱s-1 时，风的影响在个体间和个体内的差异以及设备的不确定性范围内，只有风速≥4 米⸱s-1 时，生理反应的差异才达到统计学意义。我们的数据表明，在跑步速度低于 4 m⸱s-1（14.4 km/h）时，室内跑步机和室外跑步在空气运动相对于人的代谢影响方面具有可比性。然而，这并不包括风的体温调节作用，由于跑步过程中自生的风，室外跑步的降温率更高。剔除核心温度上升的混杂影响后，观察到的顶风效应比之前观察到的要低，而尾风效应则比之前观察到的要大。就中长跑而言，以 21.5 km.h-1 的速度跑步时产生的顶风会导致 V̇O2 增加 2.2%。而相同速度的相对尾风则会导致降低 3.1%。

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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来源期刊

Journal of applied physiology 医学-生理学

CiteScore

6.00

自引率

9.10%

发文量

296

审稿时长

2-4 weeks

期刊介绍： The Journal of Applied Physiology publishes the highest quality original research and reviews that examine novel adaptive and integrative physiological mechanisms in humans and animals that advance the field. The journal encourages the submission of manuscripts that examine the acute and adaptive responses of various organs, tissues, cells and/or molecular pathways to environmental, physiological and/or pathophysiological stressors. As an applied physiology journal, topics of interest are not limited to a particular organ system. The journal, therefore, considers a wide array of integrative and translational research topics examining the mechanisms involved in disease processes and mitigation strategies, as well as the promotion of health and well-being throughout the lifespan. Priority is given to manuscripts that provide mechanistic insight deemed to exert an impact on the field.