Validity of NIR spectroscopy for quantitatively measuring muscle oxidative metabolic rate in exercise.

The purpose of this study was to examine the validity of the quantitative measurement of muscle oxidative metabolism in exercise by near-infrared continuous-wave spectroscopy (NIRcws). Twelve male subjects performed two bouts of dynamic handgrip exercise, once for the NIRcws measurement and once for the (31)P-magnetic resonance spectroscopy (MRS) measurement as a standard measure. The resting muscle metabolic rate (RMRmus) was independently measured by (31)P-MRS during 15 min of arterial occlusion at rest. During the first exercise bout, the quantitative value of muscle oxidative metabolic rate at 30 s postexercise was evaluated from the ratio of the rate of oxyhemoglobin/myoglobin decline measured by NIRcws during arterial occlusion 30 s after exercise and the rate at rest. Therefore, the absolute values of muscle oxidative metabolic rate at 30 s after exercise [VO(2NIR(30))] was calculated from this ratio multiplied by RMRmus. During the second exercise bout, creatine phosphate (PCr) resynthesis rate was measured by (31)P-MRS at 30 s postexercise [Q((30))] under the same conditions but without arterial occlusion postexercise. To determine the validity of NIRcws, VO(2NIR(30)) was compared with Q((30)). There was a significant correlation between VO(2NIR(30)), which ranged between 0.018 and 0. 187 mM ATP/s, and Q((30)), which ranged between 0.041 and 0.209 mM ATP/s (r = 0.965, P < 0.001). This result supports the application of NIRcws to quantitatively evaluate muscle oxidative metabolic rate in exercise.

[1]  E. Hultman,et al.  Glycogen, glycolytic intermediates and high-energy phosphates determined in biopsy samples of musculus quadriceps femoris of man at rest. Methods and variance of values. , 1974, Scandinavian journal of clinical and laboratory investigation.

[2]  D. Gadian,et al.  Bioenergetics of intact human muscle. A 31P nuclear magnetic resonance study. , 1983, Molecular biology & medicine.

[3]  G. Radda,et al.  Comparisons of ATP turnover in human muscle during ischemic and aerobic exercise using 31P magnetic resonance spectroscopy , 1994, Magnetic resonance in medicine.

[4]  P. Matthews,et al.  metabolic recovery after exercise and the assessment of mitochondrial function in Vivo in human skeletal muscle by means of 31P NMR , 1984, Magnetic resonance in medicine.

[5]  C. Fraser,et al.  A 31p Nuclear Magnetic Resonance Study , 1988 .

[6]  M. Mahler First-order kinetics of muscle oxygen consumption, and an equivalent proportionality between QO2 and phosphorylcreatine level. Implications for the control of respiration , 1985, The Journal of general physiology.

[7]  M. Kushmerick,et al.  Glycolysis is independent of oxygenation state in stimulated human skeletal muscle in vivo , 1998, The Journal of physiology.

[8]  R. Meyer,et al.  A linear model of muscle respiration explains monoexponential phosphocreatine changes. , 1988, The American journal of physiology.

[9]  Z Wang,et al.  Simultaneous in vivo measurements of HbO2 saturation and PCr kinetics after exercise in normal humans. , 1994, Journal of applied physiology.

[10]  T. Binzoni,et al.  Non-Invasive Measurements of O2 Availability in Human Skeletal Muscle with Near-Infrared Spectroscopy , 1992, International journal of sports medicine.

[11]  B Chance,et al.  Recovery from exercise-induced desaturation in the quadriceps muscles of elite competitive rowers. , 1992, The American journal of physiology.

[12]  H Eda,et al.  Near-infrared estimation of O2 supply and consumption in forearm muscles working at varying intensity. , 1996, Journal of applied physiology.

[13]  C. Piantadosi,et al.  Near infrared monitoring of human skeletal muscle oxygenation during forearm ischemia. , 1988, Journal of applied physiology.

[14]  J. Kent‐Braun,et al.  Noninvasive measurements of activity-induced changes in muscle metabolism. , 1991, Journal of biomechanics.

[15]  H Eda,et al.  New instrument for monitoring hemoglobin oxygenation. , 1989, Advances in experimental medicine and biology.

[16]  Britton Chance,et al.  A New Method for the Evaluation of Muscle Aerobic Capacity in Relation to Physical Activity Measured by Near-Infrared Spectroscopy , 1992 .

[17]  M. Kushmerick,et al.  Separate measures of ATP utilization and recovery in human skeletal muscle. , 1993, The Journal of physiology.

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

[19]  J. Leigh,et al.  Relationships between in vivo and in vitro measurements of metabolism in young and old human calf muscles. , 1993, Journal of applied physiology.

[20]  B Chance,et al.  Noninvasive measures of oxidative metabolism on working human muscles by near-infrared spectroscopy. , 1996, Journal of applied physiology.

[21]  S Nioka,et al.  Control of oxidative metabolism and oxygen delivery in human skeletal muscle: a steady-state analysis of the work/energy cost transfer function. , 1985, Proceedings of the National Academy of Sciences of the United States of America.

[22]  B. Saltin,et al.  NMR and analytic biochemical evaluation of CrP and nucleotides in the human calf during muscle contraction. , 1993, Journal of applied physiology.

[23]  L Bolinger,et al.  Validation of near-infrared spectroscopy in humans. , 1994, Journal of applied physiology.

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