Skeletal muscle metabolism during exercise and recovery in patients with respiratory failure.

BACKGROUND--Patients with respiratory failure have early fatiguability which may be due to limitation of oxygen supply for oxidative (mitochondrial) ATP synthesis. Skeletal muscle in exercise and recovery was studied to examine the effect of chronic hypoxia on mitochondrial activity in vivo. METHODS--The skeletal muscle of five patients with respiratory failure (PaO2 < 9 kPa) was studied by phosphorus-31 magnetic resonance spectroscopy and compared with 10 age and sex matched controls. Patients lay in a 1.9 Tesla superconducting magnet with the gastrocnemius muscle overlying a six cm surface coil. Spectra were acquired at rest, during plantar flexion exercise, and during recovery from exercise. Relative concentrations of inorganic phosphate (Pi), phosphocreatine (PCr) and ATP were measured from peak areas, and pH and free ADP concentration were calculated. For the start of exercise, the rates of PCr depletion and estimated lactic acid production were calculated. For the post exercise recovery period, the initial rate of PCr recovery (a quantitative measure of mitochondrial ATP synthesis), the apparent Vmax for mitochondrial ATP synthesis (calculated from initial PCr resynthesis and the end exercise ADP concentration which drives this process), and the recovery half times of PCr, Pi, and ADP (also measures of mitochondrial function) were determined. RESULTS--Considerably greater and faster PCr depletion and intracellular acidosis were found during exercise. This is consistent with limitation of oxygen supply to the muscle and might explain the early fatiguability of these patients. There was no abnormality in recovery from exercise, however, suggesting that mitochondria function normally after exercise. CONCLUSIONS--These results are consistent with one or more of the following: (a) decreased level of activity of these patients; (b) changes in the fibre type of the muscle; (c) decreased oxygen supply to the muscle during exercise but not during recovery. They are not consistent with an intrinsic defect of mitochondrial ATP synthesis in skeletal muscle in respiratory failure.

[1]  G. Radda,et al.  Physical training improves skeletal muscle metabolism in patients with chronic heart failure. , 1993, Journal of the American College of Cardiology.

[2]  L. Jorfeldt,et al.  Skeletal muscle metabolites and fibre types in patients with advanced chronic obstructive pulmonary disease (COPD), with and without chronic respiratory failure. , 1990, The European respiratory journal.

[3]  B. Ekblom,et al.  Hemodynamic response to work at simulated altitude, 4,000 m. , 1966, Journal of applied physiology.

[4]  M. Esbjörnsson,et al.  Increase in the proportion of fast-twitch muscle fibres by sprint training in males. , 1990, Acta physiologica Scandinavica.

[5]  B. Saltin,et al.  Muscle metabolites and oxygen deficit with exercise in hypoxia and hyperoxia. , 1974, Journal of applied physiology.

[6]  G. Radda,et al.  Abnormalities in skeletal muscle metabolism in cyanotic patients with congenital heart disease: a 31P nuclear magnetic resonance spectroscopy study. , 1993, Clinical science.

[7]  K. Angquist,et al.  Intermittent claudication and muscle fiber fine structure: correlation between clinical and morphological data. , 1980, Ultrastructural pathology.

[8]  E. Coyle,et al.  Effect of heart failure on skeletal muscle in dogs. , 1992, The American journal of physiology.

[9]  P. Macklem,et al.  Respiratory muscles: the vital pump. , 1980, Chest.

[10]  D. Gadian,et al.  EXERCISE-INDUCED ATP DEPLETION IN NORMAL HUMAN-MUSCLE , 1984 .

[11]  E. Asmussen,et al.  Pulmonary ventilation and effect of oxygen breathing in heavy exercise. , 1958, Acta physiologica Scandinavica.

[12]  D. Arnold,et al.  Investigation of human mitochondrial myopathies by phosphorus magnetic resonance spectroscopy , 1985, Annals of neurology.

[13]  G. Radda,et al.  The production, buffering and efflux of protons in human skeletal muscle during exercise and recovery , 1993, NMR in biomedicine.

[14]  B. Chance,et al.  Relationship of muscular fatigue to pH and diprotonated Pi in humans: a 31P-NMR study. , 1988, Journal of applied physiology.

[15]  T R Brown,et al.  Phosphorus nuclear magnetic resonance of fast- and slow-twitch muscle. , 1985, The American journal of physiology.

[16]  A. Benabid,et al.  Impairment of muscular metabolism in chronic respiratory failure. A human 31P MRS study , 1991, NMR in biomedicine.

[17]  G. Radda,et al.  Proton efflux from rat skeletal muscle in vivo: changes in hypertension. , 1992, Clinical science.

[18]  C. K. Mahutte,et al.  Theory of resistive load detection. , 1983, Respiration physiology.

[19]  H. Welch,et al.  Oxygen uptake, acid-base status, and performance with varied inspired oxygen fractions. , 1980, Journal of applied physiology: respiratory, environmental and exercise physiology.

[20]  G. Radda,et al.  Muscle metabolism in patients with peripheral vascular disease investigated by 31P nuclear magnetic resonance spectroscopy. , 1986, Clinical science.

[21]  M W Weiner,et al.  31P nuclear magnetic resonance studies of high energy phosphates and pH in human muscle fatigue. Comparison of aerobic and anaerobic exercise. , 1988, The Journal of clinical investigation.

[22]  H. Teräväinen,et al.  Histochemical changes in striated muscle in patients with intermittent claudication. , 1977, Archives of pathology & laboratory medicine.

[23]  G. Radda,et al.  Skeletal muscle bioenergetics in the chronic fatigue syndrome. , 1993, Journal of neurology, neurosurgery, and psychiatry.

[24]  T R Brown,et al.  Regulation of oxygen consumption in fast- and slow-twitch muscle. , 1992, The American journal of physiology.

[25]  A. Sargeant,et al.  Functional and structural changes after disuse of human muscle. , 1977, Clinical science and molecular medicine.

[26]  B. Chance,et al.  Wrist flexor muscles of elite rowers measured with magnetic resonance spectroscopy. , 1989, Journal of applied physiology.

[27]  K. Sahlin,et al.  Effect of decreased oxygen availability on NADH and lactate contents in human skeletal muscle during exercise. , 1987, Acta physiologica Scandinavica.

[28]  G K Radda,et al.  Control of phosphocreatine resynthesis during recovery from exercise in human skeletal muscle , 1993, NMR in biomedicine.

[29]  P. Macklem,et al.  The effects of inspiratory muscle training on exercise performance in chronic airflow limitation. , 2015, The American review of respiratory disease.

[30]  G. Grimby,et al.  The influence of prednisone on the muscle morphology and muscle enzymes in patients with rheumatoid arthritis. , 1986, Clinical science.

[31]  E. Blomstrand,et al.  Effect of hyperthyroidism on fibre-type composition, fibre area, glycogen content and enzyme activity in human skeletal muscle. , 1986, Clinical physiology.