肌肉氧饱和度与基于乳酸的运动阈值相符。

Muscle oxygen saturation rates coincide with lactate-based exercise thresholds.

作者信息

Batterson Philip M, Kirby Brett S, Hasselmann Georg, Feldmann Andri

机构信息

Biological and Population Health Sciences, Oregon State University, 17 Milam Hall, Corvallis, OR, 97331, USA.

Nike Sport Research Lab, Nike Inc, Beaverton, OR, USA.

出版信息

Eur J Appl Physiol. 2023 Oct;123(10):2249-2258. doi: 10.1007/s00421-023-05238-9. Epub 2023 Jun 1.

DOI:10.1007/s00421-023-05238-9

PMID:37261552

Abstract

INTRODUCTION

Monitoring muscle metabolic activity via blood lactate is a useful tool for understanding the physiological response to a given exercise intensity. Recent indications suggest that skeletal muscle oxygen saturation (SmO), an index of the balance between local O supply and demand, may describe and predict endurance performance outcomes.

PURPOSE

We tested the hypothesis that SmO rate is tightly related to blood lactate concentration across exercise intensities, and that deflections in SmO rate would coincide with established blood lactate thresholds (i.e., lactate thresholds 1 and 2).

METHODS

Ten elite male soccer players completed an incremental running protocol to exhaustion using 3-min work to 30 s rest intervals. Blood lactate samples were collected during rest and SmO was collected continuously via near-infrared spectroscopy from the right and left vastus lateralis, left biceps femoris and the left gastrocnemius.

RESULTS

Muscle O saturation rate (%/min) was quantified after the initial 60 s of each 3-min segment. The SmO rate was significantly correlated with blood lactate concentrations for all muscle sites; RVL, r = - 0.974; LVL, r = - 0.969; LG, r = - 0.942; LHAM, r = - 0.907. Breakpoints in SmO rate were not significantly different from LT1 or LT2 at any muscle sites (P > 0.05). Bland-Altman analysis showed speed threshold estimates via SmO rate and lactate are similar at LT2, but slightly greater for SmO rate at LT1.

CONCLUSIONS

Muscle O saturation rate appears to provide actionable information about maximal metabolic steady state and is consistent with bioenergetic reliance on oxygen and its involvement in the attainment of metabolic steady state.

摘要

引言

通过血乳酸监测肌肉代谢活动是了解对特定运动强度生理反应的有用工具。最近的迹象表明，骨骼肌氧饱和度（SmO），即局部氧供需平衡的指标，可能描述和预测耐力运动表现结果。

目的

我们检验了以下假设：在不同运动强度下，SmO变化率与血乳酸浓度密切相关，且SmO变化率的偏移将与既定的血乳酸阈值（即乳酸阈值1和2）一致。

方法

10名精英男性足球运动员完成了一项递增跑台测试，直至力竭，采用3分钟运动和30秒休息的间隔。在休息时采集血乳酸样本，并通过近红外光谱法从左右外侧股四头肌、左股二头肌和左腓肠肌连续采集SmO。

结果

在每个3分钟时间段的最初60秒后对肌肉氧饱和度变化率（%/分钟）进行量化。所有肌肉部位的SmO变化率与血乳酸浓度均显著相关；右侧股外侧肌（RVL），r = -0.974；左侧股外侧肌（LVL），r = -0.969；左腓肠肌（LG），r = -0.942；左股二头肌（LHAM），r = -0.907。在任何肌肉部位，SmO变化率的断点与乳酸阈值1或乳酸阈值2均无显著差异（P > 0.05）。Bland-Altman分析表明，在乳酸阈值2时，通过SmO变化率和乳酸得出的速度阈值估计值相似，但在乳酸阈值1时，SmO变化率的估计值略高。

结论

肌肉氧饱和度变化率似乎能提供有关最大代谢稳态的可操作信息，并且与对氧气的生物能量依赖及其在代谢稳态实现中的作用一致。

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肌肉氧饱和度与基于乳酸的运动阈值相符。

Muscle oxygen saturation rates coincide with lactate-based exercise thresholds.

作者信息

机构信息

出版信息

INTRODUCTION

PURPOSE

METHODS

RESULTS

CONCLUSIONS

引言

目的

方法

结果

结论

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