不同温度下头部浸水在运动后恢复期间的能量反应及其对无氧机械功率的影响。

Energetic responses of head-out water immersion at different temperatures during post-exercise recovery and its consequence on anaerobic mechanical power.

机构信息

School of Physiotherapy, Universidade Federal do Delta do Parnaíba, Av. São Sebastião, 2819, Parnaíba, PI, CEP: 64202-020, Brazil.

Postgraduate Program in Biomedical Sciences, Universidade Federal do Delta do Parnaíba, Parnaíba, PI, Brazil.

出版信息

Eur J Appl Physiol. 2023 Dec;123(12):2813-2831. doi: 10.1007/s00421-023-05265-6. Epub 2023 Jul 1.

DOI:10.1007/s00421-023-05265-6

PMID:37393218

Abstract

PURPOSE

While exercise recovery may be beneficial from a physiological point of view, it may be detrimental to subsequent anaerobic performance. To investigate the energetic responses of water immersion at different temperatures during post-exercise recovery and its consequences on subsequent anaerobic performance, a randomized and controlled crossover experimental design was performed with 21 trained cyclists.

METHOD

Participants were assigned to receive three passive recovery strategies during 10 min after a Wingate Anaerobic Test (WAnT): control (CON: non-immersed condition), cold water immersion (CWI: 20 ℃), and hot water immersion (HWI: 40 ℃). Blood lactate, cardiorespiratory, and mechanical outcomes were measured during the WAnT and its recovery. Time constant (τ), asymptotic value, and area under the curve (AUC) were quantified for each physiologic parameter during recovery. After that, a second WAnT test and 10-min recovery were realized in the same session.

RESULTS

Regardless the water immersion temperature, water immersion increased [Formula: see text] (+ 18%), asymptote ([Formula: see text]+ 16%, [Formula: see text] + 13%, [Formula: see text] + 17%, HR + 16%) and AUC ([Formula: see text]+ 27%, [Formula: see text] + 18%, [Formula: see text] + 20%, HR + 25%), while decreased [Formula: see text] (- 33%). There was no influence of water immersion on blood lactate parameters. HWI improved the mean power output during the second WAnT (2.2%), while the CWI decreased 2.4% (P < 0.01).

CONCLUSION

Independent of temperature, water immersion enhanced aerobic energy recovery without modifying blood lactate recovery. However, subsequent anaerobic performance was increased only during HWI and decreased during CWI. Despite higher than in other studies, 20 °C effectively triggered physiological and performance responses. Water immersion-induced physiological changes did not predict subsequent anaerobic performance.

摘要

目的

虽然从生理学角度来看，运动后的恢复可能有益，但它可能对随后的无氧表现产生不利影响。为了研究不同温度下的浸水在运动后恢复过程中的能量反应及其对随后的无氧表现的影响，采用随机对照交叉实验设计，对 21 名训练有素的自行车手进行了研究。

方法

参与者在进行一次沃金顿无氧测试（WAnT）后 10 分钟内接受了三种被动恢复策略：对照（CON：非浸入式条件）、冷水浸泡（CWI：20℃）和热水浸泡（HWI：40℃）。在 WAnT 及其恢复过程中测量血乳酸、心肺和机械结果。在恢复过程中，量化了每个生理参数的时间常数（τ）、渐近值和曲线下面积（AUC）。之后，在同一时段内进行了第二次 WAnT 测试和 10 分钟的恢复。

结果

无论水浸温度如何，水浸都会增加 [Formula: see text]（+18%）、渐近值（[Formula: see text]+16%，[Formula: see text]+13%，[Formula: see text]+17%，HR+16%）和 AUC（[Formula: see text]+27%，[Formula: see text]+18%，[Formula: see text]+20%，HR+25%），而 [Formula: see text]则减少（-33%）。水浸对血乳酸参数没有影响。HWI 提高了第二次 WAnT 的平均功率输出（2.2%），而 CWI 降低了 2.4%（P<0.01）。

结论

无论温度如何，水浸都能增强有氧能量恢复，而不会改变血乳酸的恢复。然而，随后的无氧表现仅在 HWI 时增加，而在 CWI 时减少。尽管 20℃的水比其他研究中的水更能有效地引发生理和表现反应，但它确实有效。水浸引起的生理变化并不能预测随后的无氧表现。

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不同温度下头部浸水在运动后恢复期间的能量反应及其对无氧机械功率的影响。

Energetic responses of head-out water immersion at different temperatures during post-exercise recovery and its consequence on anaerobic mechanical power.

机构信息

出版信息

PURPOSE

METHOD

RESULTS

CONCLUSION

目的

方法

结果

结论

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