Purpose <p>To determine which age-related alterations in muscle bioenergetic system parameters could explain variability between different experimental studies concerning changes in muscle fatigability and bioenergetics comparing young and old groups during all-out (AOE) knee-extension (KE) exercise.</p> Methods <p>A computer model of the skeletal muscle bioenergetic system involving the each-step activation (ESA) mechanism of oxidative phosphorylation (OXPHOS) regulation during work transitions and the Pi<sub>peak</sub>-P<sub>i</sub>-distance mechanism of muscle fatigue in AOE was used.</p> Results <p>Differences between young and old individuals can be explained by changes in only three parameter values: a reduction in the maximal ATP usage activity (A<sub>UTref</sub>, proportional to the maximal power), a fall in OXPHOS activity (k<sub>OX</sub>), and changes in Pi<sub>peak</sub>, the peak P<sub>i</sub> at which task failure occurs in constant power-exercise (CPE) and which is approached asymptotically by P<sub>i</sub> in AOE. Fatigability decreases with ageing when k<sub>OX</sub> declines less than A<sub>UTref</sub>, whereas fatigability increases when k<sub>OX</sub> declines more than A<sub>UTref</sub> and/or Pi<sub>peak</sub> increases. The model also demonstrates that phosphocreatine (PCr) recovery kinetics are not only influenced by k<sub>OX</sub>, but also more strongly by the ESA decay kinetics after exercise termination.</p> Conclusions <p>These findings provide a mechanistic framework within which to interpret the often inconsistent findings in the literature concerning ageing and skeletal muscle fatigability using only a few parameter values, although the contribution of other factors cannot be excluded. Older muscle behaves to a large extent like significantly detrained muscle, highlighting the role of physical activity and training in improving muscle performance and delaying fatigue with ageing.</p>

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Mechanisms underlying age-related changes in the human skeletal muscle bioenergetic system

  • Bernard Korzeniewski,
  • Richie P. Goulding

摘要

Purpose

To determine which age-related alterations in muscle bioenergetic system parameters could explain variability between different experimental studies concerning changes in muscle fatigability and bioenergetics comparing young and old groups during all-out (AOE) knee-extension (KE) exercise.

Methods

A computer model of the skeletal muscle bioenergetic system involving the each-step activation (ESA) mechanism of oxidative phosphorylation (OXPHOS) regulation during work transitions and the Pipeak-Pi-distance mechanism of muscle fatigue in AOE was used.

Results

Differences between young and old individuals can be explained by changes in only three parameter values: a reduction in the maximal ATP usage activity (AUTref, proportional to the maximal power), a fall in OXPHOS activity (kOX), and changes in Pipeak, the peak Pi at which task failure occurs in constant power-exercise (CPE) and which is approached asymptotically by Pi in AOE. Fatigability decreases with ageing when kOX declines less than AUTref, whereas fatigability increases when kOX declines more than AUTref and/or Pipeak increases. The model also demonstrates that phosphocreatine (PCr) recovery kinetics are not only influenced by kOX, but also more strongly by the ESA decay kinetics after exercise termination.

Conclusions

These findings provide a mechanistic framework within which to interpret the often inconsistent findings in the literature concerning ageing and skeletal muscle fatigability using only a few parameter values, although the contribution of other factors cannot be excluded. Older muscle behaves to a large extent like significantly detrained muscle, highlighting the role of physical activity and training in improving muscle performance and delaying fatigue with ageing.