Coupling of ventilation to pulmonary gas exchange during nonsteady-state work in men

Abstract

During steady-state exercise, ventilation increases in proportion to CO2 output (.ovrhdot.VCO2), regulating arterial PCO2 [partial pressure]. To characterize the dynamics of ventilatory coupling to .ovrhdot.VCO2 and O2 uptake (.ovrhdot.VO2) in the nonsteady-state phase, 7 normal subjects performed constant-load cycle ergometry to a series of subanaerobic threshold work rates. Each bout consisted of eight 6-min periods of alternating loaded and unloaded cycling. Ventilation and gas exchange variables were computed breath-by-breath, with the time-averaged response dynamics being established off-line. Ventilation increased as a linear function of .ovrhdot.VO2 in all cases, the relationship being identical in the steady- and the nonsteady-state phases. Ventilation bore a curvilinear relation to .ovrhdot.VO2, the kinetics of the latter being more rapid. Owing to the kinetic disparity between expired minute ventilation (.ovrhdot.VE) and .ovrhdot.VO2, there was an overshoot in the direction of change in .ovrhdot.VE/.ovrhdot.VO2 and end-tidal PO2 during the work-rate transition. There was no overshoot in the direction of change in .ovrhdot.VE/.ovrhdot.VCO2 and end-tidal PCO2 throughout the nonsteady-state period. Apparently, exercise hyperpnea is coupled to metabolism in men via a signal proportional to .ovrhdot.VCO2 in both the nonsteady and steady states of moderate exercise.