Jerzy A. Zoladz scite author profile

During high-intensity submaximal exercise, muscle fatigue and decreased efficiency are intertwined closely, and each contributes to exercise intolerance. Fatigue and muscle inefficiency share common mechanisms, for example, decreased "metabolic stability," muscle metabolite accumulation, decreased free energy of adenosine triphosphate breakdown, limited O2 or substrate availability, increased glycolysis, pH disturbance, increased muscle temperature, reactive oxygen species production, and altered motor unit recruitment patterns.

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A model of oxidative phosphorylation in mammalian skeletal muscle

Korzeniewski

Zoladz

2001

Biophysical Chemistry

169

184

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Non‐linear relationship between O2 uptake and power output at high intensities of exercise in humans.

Zoladz

Rademaker

Sargeant

1995

The Journal of Physiology

146

129

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1. A slow component to pulmonary oxygen uptake (V02) is reported during prolonged high power exercise performed at constant power output at, or above, approximately 60 % of the maximal oxygen uptake. The magnitude of the slow component is reported to be associated with the intensity of exercise and to be largely accounted for by an increased V0, across the exercising legs.2. On the assumption that the control mechanism responsible for the increased V02 is intensity dependent we hypothesized that it should also be apparent in multi-stage incremental exercise tests with the result that the V102-power output relationship would be curvilinear.3. We further hypothesized that the change in the 102-power output relationship could be related to the hierarchical recruitment of different muscle fibre types with a lower mechanical efficiency. 4. Six subjects each performed five incremental exercise tests, at pedalling rates of 40, 60, 80, 100 and 120 rev min-1, over which range we expected to vary the proportional contribution of different fibre types to the power output. Pulmonary V02 was determined continuously and arterialized capillary blood was sampled and analysed for blood lactate concentration ([lactate]b). 5. Below the level at which a sustained increase in [lactate]b was observed pulmonary V02 showed a linear relationship with power output; at high power outputs, however, there was an additional increase in V02 above that expected from the extrapolation of that linear relationship, leading to a positive curvilinear V02-power output relationship.6. No systematic effect on the magnitude or onset of the 'extra' VO2 was found in relation to pedalling rate, which suggests that it is recruitment in any simple way.

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Progressive recruitment of muscle fibers is not necessary for the slow component of V̇o₂kinetics

Zoladz

Gladden²,

Hogan³

et al. 2008

Journal of Applied Physiology

125

107

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The "slow component" of O2 uptake (VO2) kinetics during constant-load heavy-intensity exercise is traditionally thought to derive from a progressive recruitment of muscle fibers. In this study, which represents a reanalysis of data taken from a previous study by our group (Grassi B, Hogan MC, Greenhaff PL, Hamann JJ, Kelley KM, Aschenbach WG, Constantin-Teodosiu D, Gladden LB. J Physiol 538: 195-207, 2002) we evaluated the presence of a slow component-like response in the isolated dog gastrocnemius in situ (n=6) during 4 min of contractions at approximately 60-70% of peak VO2. In this preparation all muscle fibers are maximally activated by electrical stimulation from the beginning of the contraction period, and no progressive recruitment of fibers is possible. Muscle VO2 was calculated as blood flow multiplied by arteriovenous O2 content difference. The muscle fatigued (force decreased by approximately 20-25%) during contractions. Kinetics of adjustment were evaluated for 1) VO2, uncorrected for force development; 2) VO2 normalized for peak force; 3) VO2 normalized for force-time integral. A slow component-like response, described in only one muscle out of six when uncorrected VO2 was considered, was observed in all muscles when VO2/peak force and VO2/force-time were considered. The amplitude of the slow component-like response, expressed as a fraction of the total response, was higher for VO2/peak force (0.18+/-0.06, means+/-SE) and for VO2/force-time (0.22+/-0.05) compared with uncorrected VO2 (0.04+/-0.04). A progressive recruitment of muscle fibers may not be necessary for the development of the slow component of VO2 kinetics, which may be caused by the metabolic factors that induce muscle fatigue and, as a consequence, reduce the efficiency of muscle contractions.

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Factors determining the oxygen consumption rate (V.o2) on-kinetics in skeletal muscles

Korzeniewski

Zoladz

2004

104

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Using a computer model of oxidative phosphorylation developed previously [Korzeniewski and Mazat (1996) Biochem. J. 319, 143-148; Korzeniewski and Zoladz (2001) Biophys. Chem. 92, 17-34], we analyse the effect of several factors on the oxygen-uptake kinetics, especially on the oxygen consumption rate (VO2) and half-transition time t(1/2), at the onset of exercise in skeletal muscles. Computer simulations demonstrate that an increase in the total creatine pool [PCr+/-Cr] (where Cr stands for creatine and PCr for phosphocreatine) and in glycolytic ATP supply lengthen the half-transition time, whereas increase in mitochondrial content, in parallel activation of ATP supply and ATP usage, in oxygen concentration, in proton leak, in resting energy demand, in resting cytosolic pH and in initial alkalization decrease this parameter. Theoretical studies show that a decrease in the activity of creatine kinase (CK) [displacement of this enzyme from equilibrium during on-transient (rest-to-work transition)] accelerates the first stage of the VO2 on-transient, but slows down the second stage of this transient. It is also demonstrated that a prior exercise terminated a few minutes before the principal exercise shortens the transition time. Finally, it is shown that at a given ATP demand, and under conditions where CK works near the thermodynamic equilibrium, the half-transition time of VO2 kinetics is determined by the amount of PCr that has to be transformed into Cr during rest-to-work transition; therefore any factor that diminishes the difference in [PCr] between rest and work at a given energy demand will accelerate the VO2 on-kinetics. Our conclusions agree with the general idea formulated originally by Easterby [(1981) Biochem. J. 199, 155-161] that changes in metabolite concentrations determine the transition times between different steady states in metabolic systems.

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Jerzy A. Zoladz

Skeletal Muscle Fatigue and Decreased Efficiency

A model of oxidative phosphorylation in mammalian skeletal muscle

Non‐linear relationship between O2 uptake and power output at high intensities of exercise in humans.

Progressive recruitment of muscle fibers is not necessary for the slow component of V̇o₂kinetics

Factors determining the oxygen consumption rate (V.o2) on-kinetics in skeletal muscles

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Jerzy A. Zoladz

Skeletal Muscle Fatigue and Decreased Efficiency

A model of oxidative phosphorylation in mammalian skeletal muscle

Non‐linear relationship between O2 uptake and power output at high intensities of exercise in humans.

Progressive recruitment of muscle fibers is not necessary for the slow component of V̇o2kinetics

Factors determining the oxygen consumption rate (V.o2) on-kinetics in skeletal muscles

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Product

Resources

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Progressive recruitment of muscle fibers is not necessary for the slow component of V̇o₂kinetics