The role of pulmonary CO2 flow in the control of the phase i ventilatory response to exercise in humans

To gain an insight into the origin of the phase I ventilatory response to exercise (ph I) in humans, pulmonary ventilation WE) and end-tidal partial pressures of oxygen and carbon dioxide (P_ETO₂ and P_ETCO₂, respectively) were measured breath-by-breath in six male subjects during constant-intensity exercise on the cycle ergometer at 50, 100 and 150 W, with eupnoeic normocapnia (N) or hyperpnoeic hypocapnia (H) established prior to the exercise test. Cardiac output (Q₂) was also determined beat-by-beat by impedance cardiography on eight subjects during moderate exercise (50 W), and the C0₂ flow to the lungs (Q₂·C_vCO₂ where C_vCO₂ is concentration of CO₂ in mixed veneous blood) was estimated with a time resolution of one breathing cycle. In N, the initial abrupt increase of PE during ph I (V_E approximately 18 l · min^–1 above rest) was followed by a transient fall. When P_ETCO₂ started to increase (and P_ETO₂ decreased) V_E increased again (phase II ventilatory response, ph II). In H, during ph I V_E was similar to that of N. By contrast, during ph II V_E kept gradually decreasing and started to increase only when P_ETCO₂ had returned to approximately 40 mmHg (5.3 kPa). Thus, as a result of the prevailing initial conditions (N or H) a temporal shift of the time-course of V_E during ph II became apparent. No correlation was found between C0₂ flow to the lungs and V_E during ph I. These results are interpreted as suggesting that an increased C0₂ flow to the lungs does not constitute an important factor for the initial hyperventilatory response to exercise. They are rather compatible with a neural origin of ph I, and would support the neurohumoral theory of ventilatory control during exercise.