It has recently been reported that the 'gain' of Phase II increase in pulmonary oxygen uptake (i.e. the 'fundamental' increase in V(O(2)) per unit increase in work rate; G(p)) does not attain the anticipated value of approximately 10 ml min(-1)W(-1) following the onset of high-intensity exercise. In the present study, we hypothesised that G(p) would fall significantly below 10 ml min(-1)W(-1) only when the work rate exceeded the so-called 'critical power' (CP). Seven healthy males completed several 'square-wave' transitions from 'unloaded' cycling to work rates requiring 60 and 90% of the gas exchange threshold (GET), 40 and 80% of the difference between the GET and V(O(2)) peak (i.e. below and above the CP, respectively), and 100, 110 and 120% of V(O(2)) peak. Pulmonary V(O(2)) was measured breath-by-breath and V(O(2)) kinetics were determined using non-linear regression techniques. The asymptotic G(p) was significantly lower at work rates above (7.2-8.6 ml min(-1)W(-1)) compared to work rates below (9.3-9.7 ml min(-1)W(-1)) the CP (P < 0.05). We conclude that the gain of Phase II increase in V(O(2)) becomes significantly reduced when the work rate exceeds the CP.