The adjustment of pulmonary oxygen uptake (VO2) following a step increase in work rate has been characterized as consisting of an
early "cardiodynamic" component with unchanged mixed-venous O2-content ("phase 1") and a subsequent "metabolic" component ("phase 2") starting when
venous blood from the muscle arrives at the lungs. The aim of the present study was
to investigate whether the onset of phase 2 actually indicates the arrival of blood
influenced by the altered muscle metabolism. Parallel measurements of cardiac output
(Doppler technique) and VO2 (breath-by-breath measurements at the mouth) were performed in eight subjects during
step increases in exercise intensity (from a 20 W baseline to either 80 W, 120 W,
160 W or 200 W). To vary the absolute cardiac output values for given muscle VO2 the subjects exercised both in upright and supine position. Individual time-courses
of the arterio-venous O2 difference (a-v ΔO2) were computed from cardiac output and VO2 data. Independent of body position two clear-cut phases of similar duration were
seen both in VO2 and in the computed a-v ΔO2. The duration of the first component with unchanged a-v ΔO2 was about 20 s at the lowest step amplitudes (20 - 80 W and 20 - 120 W). It decreased
to about 15 s for the 20 - 160 W and 20 - 200 W steps. At the lower exercise intensities
the duration of phase 1 appears too long to be entirely due to the transit time of
venous blood from the exercising muscles to the lungs. The present data rather suggest
that, at lower exercise intensities, there is no abrupt decrease in venous O2-content in the muscle so that the arrival of muscle blood at the lungs cannot simply
be discerned by means of the respiratory VO2 measurements or computed a-v ΔO2 time courses.
Key words
Cardiac output dynamics - oxygen uptake dynamics - cycle exercise - body position
- humans
