Relationships between (V) over dotO2 and blood lactate responses after all-out running exercise

To verify the effects of training status and blood lactate concentration (BLC) responses on the early excess postexercise oxygen consumption (EPOC), 8 sprinters, 7 endurance runners, and 7 untrained subjects performed an incremental test to determine maximal oxygen uptake and a 1-min all-out test to determine BLC and oxygen uptake recovery curves. BLC kinetics was evaluated to assess the quantity of lactate accumulated during exercise (Q(laA)), lactate removal ability (k(2)), and quantity of lactate removed from 0 to 10 min postexercise (Q(laR)). Oxygen uptake off-kinetics was evaluated to assess the decay time constants (tau(1) and tau(2)); moreover, EPOC was measured during the first 10 min after exercise. While sprinters had 98%-100% and 94%-100% likelihood of having the highest EPOC and decay time constants, endurance runners had 98%-100% and 95%-100% likelihood of having the lowest EPOC and decay time constants. EPOC was correlated with Q(laA) (r = 0.74) and Q(laR) (r = 0.61). tau(1) and tau(2) were correlated with maximal oxygen uptake (r > -0.57), k(2) (r > -0.48), and Q(laR) relative to Q(laA) (r > -0.60). Our findings indicate that oxygen uptake recovery is associated with fast lactate removal and aerobic training. Furthermore, the metabolites derived from anaerobic energy production seem to induce a greater EPOC after all-out exercise.