无氧代谢在血流限制下运动时会导致更大的总能量消耗。

Anaerobic metabolism induces greater total energy expenditure during exercise with blood flow restriction.

机构信息

Exercise Physiology Lab., School of Physical Education, University of Campinas-Campinas/Brazil.

School of Physical Education and Sport, University of São Paulo, São Paulo, Brazil.

出版信息

PLoS One. 2018 Mar 29;13(3):e0194776. doi: 10.1371/journal.pone.0194776. eCollection 2018.

DOI:10.1371/journal.pone.0194776

PMID:29596452

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5875813/

Abstract

PURPOSE

We investigated the energy system contributions and total energy expenditure during low intensity endurance exercise associated with blood flow restriction (LIE-BFR) and without blood flow restriction (LIE).

METHODS

Twelve males participated in a contra-balanced, cross-over design in which subjects completed a bout of low-intensity endurance exercise (30min cycling at 40% of [Formula: see text]) with or without BFR, separated by at least 72 hours of recovery. Blood lactate accumulation and oxygen uptake during and after exercise were used to estimate the anaerobic lactic metabolism, aerobic metabolism, and anaerobic alactic metabolism contributions, respectively.

RESULTS

There were significant increases in the anaerobic lactic metabolism (P = 0.008), aerobic metabolism (P = 0.020), and total energy expenditure (P = 0.008) in the LIE-BFR. No significant differences between conditions for the anaerobic alactic metabolism were found (P = 0.582). Plasma lactate concentration was significantly higher in the LIE-BFR at 15min and peak post-exercise (all P≤0.008). Heart rate was significantly higher in the LIE-BFR at 10, 15, 20, 25, and 30min during exercise, and 5, 10, and 15min after exercise (all P≤0.03). Ventilation was significantly higher in the LIE-BFR at 10, 15, and 20min during exercise (all P≤0.003).

CONCLUSION

Low-intensity endurance exercise performed with blood flow restriction increases the anaerobic lactic and aerobic metabolisms, total energy expenditure, and cardiorespiratory responses.

摘要

目的

我们研究了在有血流限制（LIE-BFR）和无血流限制（LIE）条件下进行的低强度耐力运动时能量系统的贡献和总能量消耗。

方法

12 名男性参与了一项对照交叉设计的研究，其中受试者在至少 72 小时的恢复期后，分别完成了一次低强度耐力运动（30 分钟，自行车骑行，强度为[Formula: see text]的 40%）。运动中和运动后的血乳酸积累和氧气摄取分别用于估计无氧乳酸代谢、有氧代谢和无氧非乳酸代谢的贡献。

结果

在 LIE-BFR 中，无氧乳酸代谢（P=0.008）、有氧代谢（P=0.020）和总能量消耗（P=0.008）均显著增加。在 LIE-BFR 中，无氧非乳酸代谢没有显著差异（P=0.582）。在 LIE-BFR 中，运动后 15 分钟和峰值时的血浆乳酸浓度显著升高（均 P≤0.008）。在运动期间，LIE-BFR 中的心率在 10、15、20、25 和 30 分钟时以及运动后 5、10 和 15 分钟时显著升高（均 P≤0.03）。在运动期间，LIE-BFR 中的通气量在 10、15 和 20 分钟时显著升高（均 P≤0.003）。

结论

在有血流限制的情况下进行低强度耐力运动可增加无氧乳酸和有氧代谢、总能量消耗和心肺反应。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b172/5875813/d52c3fbd3351/pone.0194776.g001.jpg

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无氧代谢在血流限制下运动时会导致更大的总能量消耗。

Anaerobic metabolism induces greater total energy expenditure during exercise with blood flow restriction.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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