在相同相对强度下，对递增、间歇和持续的配重单腿及双腿骑行的生理反应。

Physiological responses to incremental, interval, and continuous counterweighted single-leg and double-leg cycling at the same relative intensities.

作者信息

MacInnis Martin J, Morris Nathaniel, Sonne Michael W, Zuniga Amanda Farias, Keir Peter J, Potvin Jim R, Gibala Martin J

机构信息

Department of Kinesiology, McMaster University, 1280 Main St. West, Hamilton, ON, L8S 4K1, Canada.

出版信息

Eur J Appl Physiol. 2017 Jul;117(7):1423-1435. doi: 10.1007/s00421-017-3635-8. Epub 2017 May 11.

DOI:10.1007/s00421-017-3635-8

PMID:28497384

Abstract

PURPOSE

We compared physiological responses to incremental, interval, and continuous counterweighted single-leg and double-leg cycling at the same relative intensities. The primary hypothesis was that the counterweight method would elicit greater normalized power (i.e., power/active leg), greater electromyography (EMG) responses, and lower cardiorespiratory demand.

METHODS

Graded-exercise tests performed by 12 men (age: 21 ± 2 years; BMI: 24 ± 3 kg/m) initially established that peak oxygen uptake ([Formula: see text]; 76 ± 8.4%), expired ventilation ([Formula: see text]; 71 ± 6.8%), carbon dioxide production ([Formula: see text]; 71 ± 6.8%), heart rate (HRpeak; 91 ± 5.3%), and power output (PPO; 56 ± 3.6%) were lower during single-leg compared to double-leg cycling (main effect of mode; p < 0.05). On separate days, participants performed four experimental trials, which involved 30-min bouts of either continuous (50% PPO) or interval exercise [4 × (5-min 65% PPO + 2.5 min 20% PPO)] in a single- or double-leg manner.

RESULTS

Double-leg interval and continuous cycling were performed at greater absolute power outputs but lower normalized power outputs compared to single-leg cycling (p < 0.001). The average EMG responses from the vastus lateralis and vastus medialis were similar across modes (p > 0.05), but semitendinosus was activated to a greater extent for single-leg cycling (p = 0.005). Single-leg interval and continuous cycling elicited lower mean [Formula: see text], [Formula: see text], [Formula: see text], HR and ratings of perceived exertion compared to double-leg cycling (p < 0.05).

CONCLUSIONS

Counterweighted single-leg cycling elicits lower cardiorespiratory and perceptual responses than double-leg cycling at greater normalized power outputs.

摘要

目的

我们比较了在相同相对强度下，递增、间歇和持续配重单腿与双腿骑行的生理反应。主要假设是，配重方法会产生更大的标准化功率（即功率/活动腿）、更大的肌电图（EMG）反应以及更低的心肺需求。

方法

12名男性（年龄：21±2岁；BMI：24±3kg/m²）进行的分级运动测试初步确定，与双腿骑行相比，单腿骑行时的峰值摄氧量（[公式：见正文]；76±8.4%）、呼气通气量（[公式：见正文]；71±6.8%）、二氧化碳产生量（[公式：见正文]；71±6.8%）、心率（HRpeak；91±5.3%）和功率输出（PPO；56±3.6%）更低（运动模式的主效应；p<0.05）。在不同的日子里，参与者进行了四项实验性试验，包括以单腿或双腿方式进行30分钟的持续（50%PPO）或间歇运动[4×（5分钟65%PPO+2.5分钟20%PPO）]。

结果

与单腿骑行相比，双腿间歇和持续骑行的绝对功率输出更高，但标准化功率输出更低（p<0.001）。不同模式下，股外侧肌和股内侧肌的平均EMG反应相似（p>0.05），但单腿骑行时半腱肌的激活程度更大（p=0.005）。与双腿骑行相比，单腿间歇和持续骑行引起的平均[公式：见正文]、[公式：见正文]、[公式：见正文]、心率和自觉用力程度更低（p<0.05）。

结论

在更高的标准化功率输出下，配重单腿骑行比双腿骑行引起的心肺和感知反应更低。

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在相同相对强度下，对递增、间歇和持续的配重单腿及双腿骑行的生理反应。

Physiological responses to incremental, interval, and continuous counterweighted single-leg and double-leg cycling at the same relative intensities.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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