A detailed comparison of oxygen uptake kinetics at a range of exercise intensities

Motriz: Revista de Educação Física Pub Date : 2019-04-29 DOI:10.1590/S1980-6574201900010010

C. Clark, S. Draper

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Abstract

It is believed that exercise performed in the heavy intensity exercise (above Gas Exchange Threshold (GXT)) domain will reach a steady state (albeit delayed). However reported modelled time constants for the slow component indicate the VO² response would not be complete within the duration of the exercise performed. This raises important questions regarding the concept of heavy intensity exercise and the suitability of current exponential models to describe the slow component of VO². .The purpose of this study was; to comprehensively describe the relationship between exercise intensity and the slow component of VO², and to investigate whether a steady-state in VO² was achieved during constant work-rates above the gas exchange threshold (GXT). Eight recreationally active male participants volunteered for this study (age: 24±8 y; Stature: 1.78±0.09 m; mass: 76.5±10.1 kg; VO²peak: 3.89±0.72 L.min-1). The participants were required to visit the laboratory on nine occasions for testing. The first visit involved determination of GXT and VO²peak with a progressive ramp exercise test. The following tests involved multiple laboratory visits, with the participants performing a square wave transition from rest to one of eight exercise intensities; -20%Δ (minus 20% of the difference in VO² between that at GXT and VO2peak), -10%Δ, GXT, 10%Δ, 20%Δ, 30%Δ, 40%Δ and 50%Δ. The VO² response was modelled using both mono and bi exponential non-linear regression techniques. Difference in the SEE for the mono and bi exponential models were analysed using a paired samples t-test, and the slope of VO² vs Time (for the final minute of exercise) was analysed using a one-sample t-test. A slow component of VO² was found for all exercise intensities. The SEE’s were significantly lower in the bi vs. mono exponential model across all exercise intensities (p<0.05). The slope was not different from 0 (p<0.05) for the final minute of any exercise intensity, indicating that a steady-state was achieved. The modelled slow component time constants are typical of literature reported values, but would indicate that VO² would not be achieved during the duration of the exercise. These findings demonstrate that VO² was in steady-state for all exercise intensities for the final minute of exercise. These findings also demonstrate that using a bi exponential model, a slow component can be modelled even below GXT and that the time constant of the slow component would be too long to result a steady-state.

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在一系列运动强度下的氧摄取动力学的详细比较

据认为，在高强度运动(高于气体交换阈值(GXT))域中进行的运动将达到稳定状态(尽管延迟)。然而，报告的慢速分量的模拟时间常数表明，在进行的演习期间，VO²响应不会完成。这提出了关于高强度运动的概念和当前指数模型描述VO²慢分量的适用性的重要问题。全面描述运动强度与VO²慢速组分之间的关系，并研究在高于气体交换阈值(GXT)的恒定工作速率下，VO²是否达到稳态。8名从事娱乐活动的男性志愿者参加了这项研究(年龄:24±8岁;身高:1.78±0.09米;质量:76.5±10.1 kg;VO²峰值:3.89±0.72 L.min-1)。参与者被要求到实验室进行9次测试。第一次访问包括用渐进式斜坡运动试验测定GXT和VO²峰值。接下来的测试包括多次实验室访问，参与者进行从休息到八种运动强度之一的方波转换;-20%Δ(减去GXT和vo2峰值之间VO²差的20%)，-10%Δ， GXT, 10%Δ， 20%Δ， 30%Δ， 40%Δ和50%Δ。利用单指数和双指数非线性回归技术对VO²响应进行建模。使用配对样本t检验分析单指数模型和双指数模型的SEE差异，使用单样本t检验分析VO²与时间(运动的最后一分钟)的斜率。在所有的运动强度下都发现了一个缓慢的VO²成分。在所有运动强度中，双指数模型与单指数模型的SEE都显著低于(p<0.05)。在任何运动强度的最后一分钟，斜率都与0无差异(p<0.05)，表明达到了稳定状态。模拟的慢速分量时间常数是文献报道值的典型值，但表明在演习期间不会达到VO²。这些结果表明，在运动的最后一分钟，VO²在所有运动强度下都处于稳定状态。这些发现还表明，使用双指数模型，即使低于GXT，也可以对慢速分量进行建模，并且慢速分量的时间常数太长而无法产生稳态。

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Motriz: Revista de Educação Física

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