Skeletal muscle oxidative metabolism in sedentary humans: <sup>31</sup>P-MRS assessment of O<sub>2</sub> supply and demand limitations

Haseler, Luke J.; Lin, Alexander; Richardson, Russell S.

doi:10.1152/japplphysiol.01321.2003

Cited by 77 publications

(82 citation statements)

References 29 publications

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“…2). These results are consistent with the unaltered postexercise PCr recovery kinetics (Haseler et al 2004) and leg VO 2max (Cardus et al 1998) in hyperoxia compared to normoxia previously reported in young sedentary subjects and extend these findings to the elderly. These findings, therefore, reveal that the maximal rate of mitochondrial ATP synthesis in the calf muscle is determined by mitochondrial capacity rather than O 2 supply in both young and elderly sedentary individuals.…”

Section: Discussionsupporting

confidence: 91%

“…For instance, Pedersen et al (1999) reported diminished leg blood flow and a trend for a lower maximal O 2 consumption during one-leg knee extension exercise in hyperoxia compared to normoxia (Pedersen et al 1999). Interestingly, similar to the present study, Haseler et al (2004) also reported a slight increase in the PCr recovery time constant in hyperoxia compared to normoxia in young untrained individuals, although this difference was less marked (Haseler et al 2004). It cannot be ruled out that breathing hyperoxic gas mixture during our plantar flexion exercise may have resulted in hyperoxic vasoconstriction, thus compromising to some extent O 2 availability in the young untrained subjects.…”

Section: Discussionsupporting

confidence: 90%

“…Specifically, as O 2 supply appears to slow pulmonary O 2 consumption kinetics at the onset of contractions in older individuals (DeLorey et al 2007), it could be hypothesized that O 2 availability will also limit the recovery kinetics of PCr. Therefore, unlike their sedentary younger counterparts (Haseler et al 2004), an improved O 2 availability induced by breathing a hyperoxic gas mixture could accelerate the PCr recovery time constant in the older sedentary subjects. Alternatively, it could be hypothesized that, if despite the reduction in O 2 transport, intracellular PO 2 in older adults is maintained above a critical value (Wilson et al 1977;Haseler et al 2007), PCr recovery kinetics could be limited by mitochondrial capacity to generate ATP such that hyperoxia will not affect the PCr recovery time constant.…”

Section: Introductionmentioning

confidence: 98%

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Reduced muscle oxidative capacity is independent of O2 availability in elderly people

Layec

Haseler

Richardson

2012

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Impaired O 2 transport to skeletal muscle potentially contributes to the decline in aerobic capacity with aging. Thus, we examined whether (1) skeletal muscle oxidative capacity decreases with age and (2) O 2 availability or mitochondrial capacity limits the maximal rate of mitochondrial ATP synthesis in vivo in sedentary elderly individuals. We used 31 P-magnetic resonance spectroscopy ( 31 P-MRS) to examine the PCr recovery kinetics in six young (26±10 years) and six older (69±3 years) sedentary subjects following 4 min of dynamic plantar flexion exercise under different fractions of inspired O 2 (FiO 2 , normoxia 0.2; hyperoxia 1.0). End-exercise pH was not significantly different between old (7.04±0.10) and young (7.05± 0.04) and was not affected by breathing hyperoxia (old 7.08±0.08, P>0.05 and young 7.05±0.03). Likewise, end-exercise PCr was not significantly different between old (19±4 mM) and young (24±5 mM) and was not changed in hyperoxia. The PCr recovery time constant was significantly longer in the old (36±9 s) compared to the young in normoxia (23±8 s, P<0.05) and was not significantly altered by breathing hyperoxia in both the old (35±9 s) and young (29±10 s) groups. Therefore, this study reveals that the muscle oxidative capacity of both sedentary young and old individuals is independent of O 2 availability and that the decline in oxidative capacity with age is most likely due to limited mitochondrial content and/or mitochondrial dysfunction and not O 2 availability.

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Section: Discussionsupporting

confidence: 91%

Section: Discussionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 98%

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Reduced muscle oxidative capacity is independent of O2 availability in elderly people

Layec

Haseler

Richardson

2012

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“…It is upon the later unanswered question that we now focus our experiments to initially provide a benchmark for the normal healthy balance between O 2 supply and demand in ambient O 2 in untrained skeletal muscle and ultimately better understand the numerous pathologies that alter O 2 availability and metabolism either individually or in unison. Unlike maximal exercise, an advantage of assessing maximal muscle oxidative metabolism by PCr recovery from submaximal exercise is the low level of stress involved, making it suitable for studying oxidative rate during exercise under conditions of severe hypoxia, and in subjects who are unaccustomed to strenuous exercise due to inactivity, aging, or debilitating pathologies (10,14,18).Consequently, we sought to identify the critical Sa O 2 below which maximal oxidative rate would be reduced in sedentary humans by using arterial oximetry, serial reductions in O 2 availability from normoxia (FI O 2 ϭ 0.21, 0.15, 0.12, and 0.1), and 31 P magnetic resonance spectroscopy (MRS) to measure PCr recovery from plantar flexion exercise. The specific hypothesis tested was that metabolic capacity in untrained human skeletal muscle is perfectly matched to ambient O 2 availability, and hence even a modest reduction in Sa O 2 will significantly impact the maximal mitochondrial oxidative rate, as measured by PCr recovery.…”

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confidence: 99%

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confidence: 99%

Oxygen availability and PCr recovery rate in untrained human calf muscle: evidence of metabolic limitation in normoxia

Haseler¹,

Lin²,

Hoff³

et al. 2007

American Journal of Physiology-Regulatory, Integrative and Comp

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Haseler LJ, Lin A, Hoff J, Richardson RS. Oxygen availability and PCr recovery rate in untrained human calf muscle: evidence of metabolic limitation in normoxia. Am J Physiol Regul Integr Comp Physiol 293: R2046-R2051, 2007. First published August 22, 2007; doi:10.1152/ajpregu.00039.2007.-In contrast to their exercisetrained counterparts, the maximal oxidative rate of skeletal muscle in sedentary humans appears not to benefit from supplemental O 2 availability but is impacted by severe hypoxia, suggesting a metabolic limitation either at or below ambient O2 levels. However, the critical level of O2 availability at which maximal metabolic rate is reduced in sedentary humans is unknown. Using 31 P magnetic resonance spectroscopy and arterial oximetry, phosphocreatine (PCr) recovery kinetics and arterial oxygenation were assessed in six sedentary subjects performing 5-min bouts of plantar flexion exercise followed by 6 min of recovery. Each trial was repeated while breathing one of four different fractions of inspired O2 (FIO 2 ) (0.10, 0.12, 0.15, and 0.21). The PCr recovery rate constant (a marker of oxidative capacity) was unaffected by reductions in FI O 2 , remaining at a value of 1.5 Ϯ 0.2 min Ϫ1 until arterial O2 saturation (Sa O 2 ) fell to less than ϳ92%, the average value reached breathing an FI O 2 of 0.15. Below this SaO 2 , the PCr rate constant fell significantly by 13 and 31% to 1.3 Ϯ 0.2 and 1.0 Ϯ 0.2 min Ϫ1 (P Ͻ 0.05) as SaO 2 was reduced to 82 Ϯ 3 and 77 Ϯ 2%, respectively. In conclusion, this study has revealed that O 2 availability does not impact maximal oxidative rate in sedentary humans until the O 2 level falls well below that of ambient air, indicating a metabolic limitation in normoxia. oxidative capacity; 31 P-magnetic resonance spectroscopy; exercise THE REDUCED OXYGEN AVAILABILITY of severe hypoxia uniformly attenuates human maximal oxidative metabolic rate; however, limitations to maximal oxidative rate in normoxia and the impact of moderate hypoxia appear to be dependent on the exercise training status of the population studied (5,16,24). The clear dependence between O 2 supply and skeletal muscle maximal oxidative rate assessed during maximal exercise in trained human muscle has been previously recognized (24). In fact, these in vivo studies revealed that under hyperoxic conditions the maximal metabolic rate of these well-trained subjects increased beyond ambient levels, revealing O 2 supply limitation in normoxia (24). Phosphocreatine (PCr) recovery measurements, as an index of maximal oxidative rate, have provided further evidence of this O 2 supply limited maximal metabolic rate in normoxia in the muscle of exercise-trained humans but have failed to identify the level of O 2 availability that creates an O 2 surplus as this appears to fall beyond that achieved by delivering 100% O 2 (9). While a similar hyperoxic approach failed to alter the metabolic rate in the untrained muscle (Fig. 1), a unifying result is observed in both trained and untrained human skeletal muscle when seve...

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Skeletal Muscle and Exercise

Levine¹,

Levine²

2012

Metabolic Syndrome and Cardiovascular Disease

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Skeletal muscle oxidative metabolism in sedentary humans: ³¹P-MRS assessment of O₂ supply and demand limitations

Cited by 77 publications

References 29 publications

Reduced muscle oxidative capacity is independent of O2 availability in elderly people

Reduced muscle oxidative capacity is independent of O2 availability in elderly people

Oxygen availability and PCr recovery rate in untrained human calf muscle: evidence of metabolic limitation in normoxia

Skeletal Muscle and Exercise

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Skeletal muscle oxidative metabolism in sedentary humans: 31P-MRS assessment of O2 supply and demand limitations

Cited by 77 publications

References 29 publications

Reduced muscle oxidative capacity is independent of O2 availability in elderly people

Reduced muscle oxidative capacity is independent of O2 availability in elderly people

Oxygen availability and PCr recovery rate in untrained human calf muscle: evidence of metabolic limitation in normoxia

Skeletal Muscle and Exercise

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Skeletal muscle oxidative metabolism in sedentary humans: ³¹P-MRS assessment of O₂ supply and demand limitations