亚强直神经肌肉电刺激可维持温盖特试验表现，但会增加血乳酸积累。

Subtetanic neuromuscular electrical stimulation can maintain Wingate test performance but augment blood lactate accumulation.

作者信息

Takeda Ryosuke, Nojima Hiroya, Nishikawa Taichi, Okudaira Masamichi, Hirono Tetsuya, Watanabe Kohei

机构信息

Laboratory of Neuromuscular Biomechanics, School of Health and Sport Science, Chukyo University, 101 Tokodachi, Kaizu-cho, Toyota, Aichi, 470-0393, Japan.

Graduate School of Health and Sport Sciences, Chukyo University, Toyota, Japan.

出版信息

Eur J Appl Physiol. 2024 Feb;124(2):433-444. doi: 10.1007/s00421-023-05291-4. Epub 2023 Aug 3.

DOI:10.1007/s00421-023-05291-4

PMID:37535142

Abstract

PURPOSE

Concentration- and time-dependent effect of lactate on physiological adaptation (i.e., glycolytic adaptation and mitochondrial biogenesis) have been reported. Subtetanic neuromuscular electrical stimulation (NMES) with voluntary exercise (VOLES) can increase blood lactate accumulation. However, whether this is also true that VOLES can enhance the blood lactate accumulation during sprint exercise is unknown. Thus, we investigated whether VOLES before the Wingate test can enhance blood lactate accumulation without compromising Wingate exercise performance.

METHODS

Fifteen healthy young males (mean [SD], age: 23 [4] years, body mass index: 22.0 [2.1] kg/m) volunteered. After resting measurement, participants performed a 3-min intervention: VOLES (NMES with free-weight cycling) or voluntary cycling alone, which matched exercise intensity with VOLES (VOL, 43.6 [8.0] watt). Then, they performed the Wingate test with 30 min free-weight cycling recovery. The blood lactate concentration ([La]) was assessed at the end of resting and intervention, and recovery at 1, 3, 5, 10, 20, and 30 min.

RESULTS

[La] during intervention was higher with VOLES than VOL (P = 0.011). The increase in [La] after the Wingate test was maintained for longer with VOLES than VOL at 10- and 20-min recovery (P = 0.014 and 0.023, respectively). Based on the Wingate test, peak power, mean power, and the rate of decline were not significantly different between VOLES and VOL (P = 0.184, 0.201, and 0.483, respectively).

CONCLUSION

The combination of subtetanic NMES with voluntary exercise before the Wingate test has the potential to enhance blood lactate accumulation. Importantly, this combined approach does not compromise Wingate exercise performance compared to voluntary exercise alone.

摘要

目的

已有报道称乳酸对生理适应（即糖酵解适应和线粒体生物发生）具有浓度和时间依赖性效应。次强直神经肌肉电刺激（NMES）联合自主运动（VOLES）可增加血乳酸积累。然而，VOLES是否也能在短跑运动中增强血乳酸积累尚不清楚。因此，我们研究了在温盖特测试前进行VOLES是否能在不影响温盖特运动表现的情况下增强血乳酸积累。

方法

15名健康年轻男性（平均[标准差]，年龄：23[4]岁，体重指数：22.0[2.1]kg/m²）自愿参与。在静息测量后，参与者进行3分钟干预：VOLES（NMES联合自由重量骑行）或单独自主骑行，自主骑行的运动强度与VOLES匹配（VOL，43.6[8.0]瓦）。然后，他们进行温盖特测试，并进行30分钟自由重量骑行恢复。在静息和干预结束时以及恢复1、3、5、10、20和30分钟时评估血乳酸浓度（[La]）。

结果

VOLES干预期间的[La]高于VOL（P = 0.011）。在温盖特测试后，VOLES在恢复10分钟和20分钟时[La]的增加维持时间比VOL更长（分别为P = 0.014和0.023）。基于温盖特测试，VOLES和VOL之间的峰值功率、平均功率和下降速率无显著差异（分别为P = 0.184、0.201和0.483）。

结论

在温盖特测试前，次强直NMES与自主运动相结合有可能增强血乳酸积累。重要的是，与单独自主运动相比，这种联合方法不会影响温盖特运动表现。

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亚强直神经肌肉电刺激可维持温盖特试验表现，但会增加血乳酸积累。

Subtetanic neuromuscular electrical stimulation can maintain Wingate test performance but augment blood lactate accumulation.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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