Validity of exercise intensity setting using blood lactate levels.

IF 1.3 4区医学 Q3 SPORT SCIENCES

Journal of Sports Medicine and Physical Fitness Pub Date : 2025-09-05 DOI:10.23736/S0022-4707.25.16755-8

Momoko Kobayashi, Natsuki Yamamura, Takahiro Mukaimoto, Shinya Yanagita, Tatsunori Suzuki

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引用次数: 0

Abstract

Background: Exercise intensity is commonly determined using maximal heart rate and maximal oxygen uptake. However, blood lactate levels at different exercise intensities are considered more sensitive biomarkers of endurance performance than maximal oxygen uptake. This study evaluated the validity of exercise intensity determined by blood lactate levels during running and determine the dynamics of blood glucose and β-hydroxybutyrate levels during high- and low-intensity running exercise.

Methods: Exercise intensities for 12 participants were determined using the lactate curve test. Each participant performed four running tests: low-intensity 30-min, high-intensity 30-min, and low-intensity 60-min running, and no-running (control) tests, with intervals of 1 day to 2 weeks. Blood glucose and β-hydroxybutyrate levels were measured using fingertip puncture blood sampling before and every 30 min (up to 240 min) after the start of running.

Results: Blood glucose levels increased significantly immediately after high-intensity 30-min running test compared to the 0-time point. Blood glucose levels decreased to similar levels as that in the 0-min time point 30 min after the 30-min running test. β-hydroxybutyrate levels increased significantly every 30 min after the 150-min time point compared to the levels in the 0-min time point in the high-intensity 30-min and low-intensity 60-min running tests.

Conclusions: Using blood lactate measurements obtained from a simple device, we established high-intensity exercise conditions producing transient post-exercise blood glucose increases. Changes in glucose and β-hydroxybutyrate levels reflected energy metabolism shifts across exercise conditions. Further investigation of additional metabolic indicators will help clarify energy metabolism mechanisms at varying exercise intensities.

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利用血乳酸水平设定运动强度的有效性。

背景：运动强度通常用最大心率和最大摄氧量来确定。然而，不同运动强度下的血乳酸水平被认为比最大摄氧量更敏感的耐力表现生物标志物。本研究评估了跑步时血乳酸水平决定运动强度的有效性，并测定了高、低强度跑步运动时血糖和β-羟基丁酸水平的动态变化。方法：采用乳酸曲线法测定12名受试者的运动强度。每位参与者进行四项跑步测试：低强度30分钟、高强度30分钟、低强度60分钟跑步和无跑步（对照）测试，间隔为1天至2周。在开始跑步前和开始跑步后每30分钟（最多240分钟）用指尖穿刺采血测量血糖和β-羟基丁酸水平。结果：与0时间点相比，高强度30min跑步试验后血糖水平立即升高。30分钟跑步试验后30分钟，血糖水平降至与0分钟时间点相近。与高强度30分钟和低强度60分钟跑步试验的0分钟时间点相比，150分钟后β-羟基丁酸水平每30分钟显著升高。结论：通过简单的装置测量血乳酸，我们建立了高强度运动条件下产生短暂的运动后血糖升高。葡萄糖和β-羟基丁酸水平的变化反映了运动条件下能量代谢的变化。进一步研究其他代谢指标将有助于阐明不同运动强度下的能量代谢机制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Sports Medicine and Physical Fitness 医学-运动科学

CiteScore

2.90

自引率

5.90%

发文量

393

审稿时长

6-12 weeks

期刊介绍： The Journal of Sports Medicine and Physical Fitness publishes scientific papers relating to the area of the applied physiology, preventive medicine, sports medicine and traumatology, sports psychology. Manuscripts may be submitted in the form of editorials, original articles, review articles, case reports, special articles, letters to the Editor and guidelines.