Metabolic determinants of the onset of acidosis in exercising human muscle: a 31P-MRS study

Abstract

Onset of intracellular acidosis during muscular exercise has been generally attributed to activation or hyperactivation of nonoxidative ATP production but has not been analyzed quantitatively in terms of H+ balance, i.e., production and removal mechanisms. To address this issue, we have analyzed the relation of intracellular acidosis to H+balance during exercise bouts in seven healthy subjects. Each subject performed a 6-min ramp rhythmic exercise (finger flexions) at low frequency (LF, 0.47 Hz), leading to slight acidosis, and at high frequency (HF, 0.85 Hz), inducing a larger acidosis. Metabolic changes were recorded using 31P-magnetic resonance spectroscopy. Onset of intracellular acidosis was statistically identified after 3 and 4 min of exercise for HF and LF protocols, respectively. A detailed investigation of H+ balance indicated that, for both protocols, nonoxidative ATP production preceded a change in pH. For HF and LF protocols, H+ consumption through the creatine kinase equilibrium was constant in the face of increasing H+ generation and efflux. For both protocols, changes in pH were not recorded as long as sources and sinks for H+approximately balanced. In contrast, a significant acidosis occurred after 4 min of LF exercise and 3 min of HF exercise, whereas the rise in H+ generation exceeded the rise in H+ efflux at a nearly constant H+ uptake associated with phosphocreatine breakdown. We have clearly demonstrated that intracellular acidosis in exercising muscle does not occur exclusively as a result of nonoxidative ATP production but, rather, reflects changes in overall H+ balance.