Abstract
AIMMuscular fatigue is a complex phenomenon affected by muscle fiber type and several metabolic and ionic changes within myocytes. Mitochondria are the main determinants of muscle oxidative capacity which is also one determinant of muscle fatigability. By measuring the concentrations of intracellular stores of high-energy phosphates it is possible to estimate the energy production efficiency and metabolic recovery of the muscle. Low intrinsic aerobic capacity is known to be associated with reduced mitochondrial function. Whether low intrinsic aerobic capacity also results in slower metabolic recovery of skeletal muscle is not known. Here we studied the influence of intrinsic aerobic capacity on in vivo muscle metabolism during maximal, fatiguing electrical stimulation.METHODSAnimal subjects were genetically heterogeneous rats selectively bred to differ for non–trained treadmill running endurance, low capacity runners (LCRs) and high capacity runners (HCRs) (n = 15–19). We measured the concentrations of major phosphorus compounds and force parameters in a contracting triceps surae muscle complex using 31P-Magnetic resonance spectroscopy (31P-MRS) combined with muscle force measurement from repeated isometric twitches.RESULTSOur results demonstrated that phosphocreatine re-synthesis after maximal muscle stimulation was significantly slower in LCRs (p<0.05). LCR rats also became promptly fatigued and maintained the intramuscular pH poorly compared to HCRs. Half relaxation time (HRT) of the triceps surae was significantly longer in LCRs throughout the stimulation protocol (p≤0.05) and maximal rate of torque development (MRTD) was significantly lower in LCRs compared to HCRs from 2 min 30 s onwards (p≤0.05).CONCLUSIONWe observed that LCRs are more sensitive to fatigue and have slower metabolic recovery compared to HCRs after maximal muscle contractions. These new findings are associated with reduced running capacity and with previously found lower mitochondrial content, increased body mass and higher complex disease risk of LCRs.
Highlights
Muscular fatigue is characterized with decline of force production caused by prolonged activation of skeletal muscle
Our results demonstrated that phosphocreatine re-synthesis after maximal muscle stimulation was significantly slower in low capacity runners (LCRs) (p,0.05)
Half relaxation time (HRT) of the triceps surae was significantly longer in LCRs throughout the stimulation protocol (p#0.05) and maximal rate of torque development (MRTD) was significantly lower in LCRs compared to high capacity runners (HCRs) from 2 min 30 s onwards (p#0.05)
Summary
Muscular fatigue is characterized with decline of force production caused by prolonged activation of skeletal muscle. At a myocellular level the reduced force can be caused by various metabolic or ionic changes, such as reduced pH, accumulation of inorganic phosphate (Pi) into myocytes, decreased intracellular calcium ion (Ca2+) release or reduced sensitivity of the myofilaments to Ca2+-ions [5,6]. These changes in myocellular metabolites during muscle fatigue are often linked to each other. For example reduced pH and accumulation of Pi lead to reduced Ca2+ sensitivity and reduced maximum tension This in turn has an important contribution to the force decline, especially with repeated maximal muscle stimulation [7]
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