Summary
This study evaluated the time courses of intracellular pH and the metabolism of phosphocreatine (PCr) and inorganic phosphate (P) at the onset of four exercise intensities and recoveries. Non-invasive evaluation of continuous changes in phosphorus metabolites has become possible using31P-nuclear magnetic resonance spectroscopy (31P-MRS). After measurements at rest, six healthy male subjects performed 4 min of femoral flexion exercise at intensities of 0 (“loadless”), 10, 20 and 30 kg · m · min−1 in a 2.1 T superconducting magnet with a 67-cm bore. Measurements were continuously made during 5 min of recovery. During a series of rest-exercise-recovery procedures,31P-MRS were accumulated using 32 scans · spectrum−1 requiring 12.8 s each. At the onset of exercise, PCr decreased exponentially with a time constant of 27–32 s regardless of the exercise intensity. The time constant PCr resynthesis during recovery was about 27–40 s. The PCr kinetics were independent of exercise intensity. There were similar Pi kinetics at the onset of all types of exercise, while those of Pi recovery became significantly longer at the higher exercise intensities (P < 0.05). Furthermore, the intracellular pH indicated temporary alkalosis just at the onset of exercise, probably due to absorption of hydrogen ions by PCr hydrolysis, and then decrease at a point about 40%–50% of the preexercise PCr. The pH recovery time was longer than that for the Pi or PCr kinetics. By using a more efficient resolution system it was possible to obtain the phosphorus kinetics during exercise and to follow PCr resynthesis within the first few minutes of recovery. From our results it was concluded that in general the time course of PCr and Pi metabolism were unaffected by the exercise intensity, both at the onset of exercise and during recovery, with the exception of Pi recovery.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adams ER, Foley JM, Meyer RA (1990) Muscle buffer capacity estimated from pH changes during rest-to-work transitions. J Appl Physiol 69:968–972
Arnold DL, Matthews PM, Radda GK (1984) Metabolic recovery after exercise and the assessment of mitochondria function in vivo in human skeletal muscle by means of31P NMR. Magn Reson Med 1:307–315
Chance B, Leich JS Jr, Kent J, McCully K (1986) Metabolic control principles and31P NMR. Fed Proc 45:2915–2920
Dubuisson M (1939) Studies on the chemical processes which occur in muscle before, during and after contraction. J Physiol 94:461–482
Gardian DG, Radda GK, Dawson MJ, Wilkie DR (1982) pH measurements of cardiac and skeletal muscle using31P-NMR. In: Nuccitelli R, Deamer DW (eds) Intramuscular pH: its measurement, regulation and utilization in cellular functions. Liss, New York, pp 61–77
Gebert G, Friedman SM (1973) An implantable glass electrode used for pH measurement in working skeletal muscle. J Appl Physiol 34:122–124
Inch WR, Serebrin B, Taylor AW, Thompson RT (1986) Exercise muscle metabolism measured by magnetic resonance spectroscopy. Can J Sport Sci 11:60–65
Mahler M (1985) First-order kinetics of muscle oxygen consumption, and an equivalent proportionality between QO2 and phosphocreatine level. J Gen Physiol 86:135–165
Meyer RA (1988) A linear model of muscle respiration explains mono-exponential phosphocreatine changes. Am J Physiol 254:C548-C553
Mole PA, Coulson RL, Caton JR, Nichols BG, Barstow T (1985) In vivo31P-NMR in human muscle: transient patterns with exercise. J Appl Physiol 59:101–104
Newham DJ, Cady EB (1990) A31P study of fatigue and metabolism in human skeletal muscle with voluntary, intermittent contraction at different forces. Nucl Magn Reson Biomed 3:211–219
Pan JW, Hamm JR, Rothman DL, Shulman RD (1988) Intracellular pH in human skeletal muscle by1H NMR. Proc Natl Acad Sci USA 85:7836–7839
Sapeca AA, Sokolow DP, Graham TJ, Chance B (1987) Phosphorus nuclear magnetic resonance: a non-invasive technique for the study of muscle bioenergetics during exercise. Med Sci Sports Exerc 19:410–420
Tanoura M, Yamada K (1984) Changes in intracellular pH and inorganic phosphate concentration during and after muscle contraction as studied by time-resolved31P-NMR: alkalization by contraction. FEBS Lett 171:165–168
Whipp BJ, Mahler M (1980) Dynamics of pulmonary gas exchange during exercise. In: West JB (ed) Pulmonary gas exchange, vol 2. Academic Press, New York, pp 33–96
Whipp BJ, Ward SA, Lamarra N, Davis JA, Wasserman K (1982) Parameters of ventilatory and gas exchange dynamics during exercise. J Appl Physiol Respir Environ Exerc Physiol 52:1506–1513
Wilkie DR (1986) Muscular fatigue: effects of hydrogen ions and inorganic phosphate. Fed Proc 45:2921–2923
Yoshida T, Udo M, Ohmori T, Matsumoto Y, Uramoto T, Yamamoto K (1992) Day-to-day chances in\(\dot V\)O2 kinetics at the onset of exercise during strenuous endurance training. Eur J Appl Physiol 64:78–83
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Yoshida, T., Watari, H. 31P-Nuclear magnetic resonance spectroscopy study of the time course of energy metabolism during exercise and recovery. Europ. J. Appl. Physiol. 66, 494–499 (1993). https://doi.org/10.1007/BF00634298
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00634298