01-12-2005 | Original Article
Alveolar oxygen uptake kinetics with step, impulse and ramp exercise in humans
Published in: European Journal of Applied Physiology | Issue 5-6/2005
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The breath-by-breath
\({\dot V}{\text{O}}_{2{\text{A}}}\) of five male subjects (21.2 years ±3.2; 78.8 kg ±5.9; 179.6 cm ±5.8) was measured during a cycling exercise. Starting from a 10 W baseline, the subjects performed (i) ON and OFF step transitions (ST-ON; ST-OFF) to 50, 90, and 130 W; (ii) a ramp (R) exercise with work rate gradually increasing by 20 W min−1; (iii) impulse transitions (I) to 250 and 410 W lasting 10 and 5 s, respectively. The
\({\dot V}{\text{O}}_{2{\text{A}}}\) data was modelled using non-linear weighted least square regressions. The amplitudes of the
\({\dot V}{\text{O}}_{2{\text{A}}}\) response turned out to be proportional to the input work rate intensities in all the modalities of exercise. Time constants (τ) and time delays (t
d) of ST-ON and R responses were not significantly different, whereas those of ST-OFF were characterised by longer τ values. τ and t
d of I responses turned out to be identical to those of ST-ON when the
\({\dot V}{\text{O}}_{2{\text{A}}}\) responses were fitted using a five-component model. These results suggest that: (i) the system controlling alveolar gas exchange behaves linearly when it is forced by ST and R inputs (the ON and OFF phases being considered separate); (ii) the analysis of the I response depends strongly on the models selected to fit the
\({\dot V}{\text{O}}_{2{\text{A}}}\) data. The asymmetry between the ON and OFF responses mirrors that found between the splitting and resynthesis rates of phosphocreatine, and these results support the notion that phosphocreatine could be the main controller of the skeletal muscle respiratory turnover in humans.