Different categories of VO2 kinetics in the 'extreme' exercise intensity domain

Abstract

The aim of this study was to classify potential sub-zones within the extreme exercise domain. Eight well-trained male cyclists participated in this study. The upper boundary of the severe exercise domain (P_upper-bound) was estimated by constant-work-rate tests. Then three further extreme-work-rate tests were performed in discrete regions within the extreme domain: extreme-1) at a work-rate greater than the P_upper-bound providing an 80-110-s time to task failure; extreme-2) a 30-s maximal sprint; and extreme-3) a 4-s maximal sprint. Different functions were used to describe the behaviour of the $\dot{V}{O}_2$ kinetics over time. $\dot{V}{O}_2$ on-kinetics during extreme-1 exercise was best described by a single-exponential model (R² ≥ 0.97; SEE ≤ 0.10; p < 0.001), and recovery $\dot{V}{O}_2$ decreased immediately after the termination of exercise. In contrast, $\dot{V}{O}_2$ on-kinetics during extreme-2 exercise was best fitted by a linear function (R² ≥ 0.96; SEE ≤ 0.16; p < 0.001), and $\dot{V}{O}_2$ responses continued to increase during the first 10-20 s of recovery. During the extreme-3 exercise, $\dot{V}{O}_2$ could not be modelled due to inadequate data, and there was an M-shape recovery $\dot{V}{O}_2$ response with an exponential decay at the end. The $\dot{V}{O}_2$ response to exercise across the extreme exercise domain has distinct features and must therefore be characterised with different fitting strategies in order to describe the responses accurately.

Keywords: All-out; maximal sprint; oxygen uptake kinetics; supramaximal exercise zone.