EMG versus oxygen uptake during cycling exercise in trained and untrained subjects

Abstract

The aim of this study was to test the hypothesis that bicycle training may improve the relationship between the global SEMG energy and V ̇ O 2 . We already showed close adjustment of the root mean square (RMS) of the surface electromyogram (SEMG) to the oxygen uptake ( V ̇ O 2 ) during cycling exercise in untrained subjects. Because in these circumstances an altered neuromuscular transmission which could affect SEMG measurement occurred in untrained individuals only, we searched for differences in the SEMG vs. V ̇ O 2 relationship between untrained subjects and well-trained cyclists. Each subject first performed an incremental exercise to determine V ̇ O 2 max and the ventilatory threshold, and second a constant-load threshold cycling exercise, continued until exhaustion. SEMG from both vastus lateralis muscles was continuously recorded. RMS was computed. M-Wave was periodically recorded. During incremental exercise: (1) a significant non-linear positive correlation was found between RMS increase and V ̇ O 2 increase in untrained subjects, whereas the relationship was best fitted by a straight line in trained cyclists; (2) the RMS/ V ̇ O 2 ratio decreased progressively throughout the incremental exercise, its decline being significantly and markedly accentuated in trained cyclists; (3) in untrained subjects, significant M-wave alterations occurred at the end of the trial. These M-wave alterations could explain the non-linear RMS increase in these individuals. During constant-load exercise: (1) after an initial increase, the RMS/ V ̇ O 2 ratio decreased progressively to reach a plateau after 2 min of exercise, but no significant inter-group differences were noted; (2) no M-wave changes were measured in the two groups. We concluded that the global SEMG energy recorded from the vastus lateralis muscle is a good estimate of metabolic energy expenditure during incremental cycling exercise only in well-trained cyclists.