UMLS:C0015672 - FACTA Search

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Query: UMLS:C0015672 (fatigue)
51,768 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Lactic acid is formed and accumulated in the muscle under conditions of high energy demand, rapid fluctuations of the energy requirement and insufficient supply of O2. During intense exercise sustained to fatigue muscle pH decreases to about 6.4-6.6. Force generation does not appear to be limited by the high H+ ion concentration per se but is more related to the PCr level. Phosphofructokinase may be inhibited by high H+ concentration but the inhibition is adequately overcome by increases in the activators AMP and ADP. A high concentration of H+ will decrease PCr by a direct effect on the creatine kinase equilibrium and indirectly by an increase in ADP. The effect of acidosis on glycolysis and on the PCr level will result in a decreased rate of ADP rephosphorylation, and it is suggested that ADP increases transiently above the steady-state level in the contracting muscle fibre. It is further suggested that the function of Na-K-ATPase is impaired by the increase of ADP resulting in an altered ionic balance over the muscle cell membrane. Muscle fatigue is thus considered to be due to an insufficient rate of ADP rephosphorylation resulting in a block in the activation process or in the excitation/contraction coupling.
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PMID:Muscle fatigue and lactic acid accumulation. 347 Oct 61

Muscle phosphorylase deficiency (McArdle's disease) has conventionally been considered a disorder of glycogenolysis, and the associated impairment in oxidative metabolism has been largely overlooked. Muscle glycogen normally is the primary oxidative fuel at exercise work loads requiring more than 75-80% of maximal O2 uptake (VO2max). Evidence is presented to support the hypothesis that a limited flux through the Embden-Myerhof pathway in McArdle's disease reduces the capacity to generate NADH required to support a normal VO2max. The extent of the oxidative defect is substrate dependent; i.e., it can be partially corrected by increasing the availability of alternative oxidative substrates (e.g., glucose, free fatty acids) to working muscle. Experiments employing modification of substrate availability closely link the hyperkinetic circulatory response to exercise (i.e., an abnormally large increase in O2 transport to skeletal muscle) and the premature muscle fatigue and cramping of McArdle patients with their oxidative impairment and suggest that a metabolic common denominator in these abnormal responses may be a pronounced decline in the muscle phosphorylation potential ([ATP]/[ADP][Pi]). The hyperkinetic circulation likely is mediated by the local effects on metabolically sensitive skeletal muscle afferents and vascular smooth muscle of K+, Pi, or adenosine or a combination of these substances released excessively from working skeletal muscle. The premature muscle fatigue and cramping of McArdle patients does not appear to be due to depletion of ATP but is associated with an increased accumulation of Pi and probably ADP in skeletal muscle. Accumulations of Pi and ADP are known to inhibit the myofibrillar, Ca2+, and Na+-K+-ATPase reactions.
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PMID:The pathophysiology of McArdle's disease: clues to regulation in exercise and fatigue. 352 13

During muscular fatigue two metabolites, hydrogen ions (H+) and inorganic phosphate (Pi), increase in concentration. The effect of increase in [H+] has been modeled mathematically for a system containing creatine kinase (EC 2.7.3.2), adenylate kinase (EC 2.7.4.3), and the appropriate concentrations of their substrates. Assuming that no other equilibrium reactions are involved, the result of acidification should be a useful increase in the ratio [ATP]/[ADP]. It is also shown by a reanalysis of earlier 31P NMR studies that the observed combination of increased [H+] and increased [Pi] leads to an increase in the monobasic phosphate concentration [Pi-] that is inversely proportional to the force of contraction. This suggests that Pi- may be a direct inhibitor of the actomyosin ATPase system.
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PMID:Muscular fatigue: effects of hydrogen ions and inorganic phosphate. 353 90

In the process of defining the recruitment of fuel and pathway selection in rainbow trout fast-twitch white skeletal muscle, it was clear that the near-maximal myosin adenosinetriphosphatase activity during a 10-s sprint was supported solely by phosphocreatine hydrolysis. A conservative estimate of the ATP turnover was 188 mumol X g wet wt-1 X min-1. It was not until the rate and force of contraction decreased that the relative contribution of anaerobic glycogenolysis became increasingly important. Over a 10-min period of burst swimming at approximately 120% of maximum aerobic steady-state swimming velocity of trout determined in a Brett-type swim tunnel, fatigue was associated with the near-depletion of glycogen in white muscle. The ATP turnover supported by anaerobic glycogenolysis was 78 mumol X g wet wt-1 X min-1. The glycolytic pathway appeared functional at this time with control sites being identified at hexokinase and phosphofructokinase (PFK-1). PFK-1 did not appear to be inhibited by low muscle pH (pH 6.66). In another exercise protocol lasting 30 min, complete exhaustion was related to glycogen depletion. The sum of all glycolytic intermediates from glucose 6-phosphate to pyruvate at exhaustion decreased by a dramatic 80% compared with the 25% decrease for the 10-min fatigue swimming protocol. This large depletion of glycolytic intermediates was accompanied by an 80% fall in ATP, a 70-80% reduction in the ATP/ADP and phosphorylation potential, and a 2.5-fold increase in the NAD/NADH. Associated with these changes was a marked displacement of the phosphoglycerate kinase (PGK), and the combined glyceraldehyde-3-phosphate dehydrogenase-PGK reactions from thermodynamic equilibrium. As a general conclusion, fatigue and exhaustion should be viewed as a multicomponent biochemical process in response to low glycogen and not leveled at one particular step of the glycolytic pathway.
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PMID:Regulation of anaerobic ATP-generating pathways in trout fast-twitch skeletal muscle. 360 83

The relationship between the redox state and lactate accumulation in contracting human skeletal muscle was investigated. Ten men performed bicycle exercise for 10 min at 40 and 75% of maximal oxygen uptake [VO2(max.)], and to fatigue (4.8 +/- 0.6 min; mean +/- S.E.M.) at 100% VO2(max.). Biopsies from the quadriceps femoris muscle were analysed for NADH, high-energy phosphates and glycolytic intermediates. Muscle NADH was 0.20 +/- 0.02 mmol/kg dry wt. of muscle at rest, and decreased to 0.12 +/- 0.01 (P less than 0.01) after exercise at 40% VO2(max.), but no change occurred in the [lactate]/[pyruvate] ratio. These data, together with previous results on isolated cyanide-poisoned soleus muscle, where NADH increased while [lactate]/[pyruvate] ratio was unchanged [Sahlin & Katz (1986) Biochem. J. 239, 245-248], suggest that the observed changes in muscle NADH occurred within the mitochondria. After exercise at 75 and 100% VO2(max.), muscle NADH increased above the value at rest to 0.27 +/- 0.03 (P less than 0.05) and 0.32 +/- 0.04 (P less than 0.001) mmol/kg respectively. Muscle lactate was unchanged after exercise at 40% VO2(max.), but increased substantially at the higher work loads. At 40% VO2(max.), phosphocreatine decreased by 11% compared with the values at rest, and decreased further at the higher work loads. The decrease in phosphocreatine reflects increased ADP and Pi. It is concluded that muscle NADH decreases during low-intensity exercise, but increases above the value at rest during high-intensity exercise. The increase in muscle NADH is consistent with the hypothesis that the accelerated lactate production during submaximal exercise is due to a limited availability of O2 in the contracting muscle. It is suggested that the increases in NADH, ADP and Pi are metabolic adaptations, which primarily serve to activate the aerobic ATP production, and that the increased anaerobic energy production (phosphocreatine breakdown and lactate formation) is a consequence of these changes.
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PMID:Redox state and lactate accumulation in human skeletal muscle during dynamic exercise. 366 77

The effect of dynamic exercise on muscle and blood ammonia (NH3) and amino acid contents has been investigated. Eight healthy men cycled at 50% and 97% of maximal oxygen uptake for 10 min and 5.2 min (to fatigue), respectively. Biopsies (quadriceps femoris muscle), arterial and femoral venous blood samples were obtained at rest and during exercise. Muscle NH3 at rest and after submaximal exercise was (means +/- SE) 0.5 +/- 0.1 mmol/kg dry muscle (d.m.) and increased to 4.1 +/- 0.5 mmol/kg d.m. at fatigue (P less than 0.001). The total adenine nucleotide (TAN) pool (TAN = ATP + ADP + AMP) did not change after submaximal exercise but decreased significantly at fatigue (P less than 0.001). The decrease in TAN was similar to the increase in NH3. Muscle lactate was 3 +/- 1 mmol/kg d.m. at rest and increased to 104 +/- 5 mmol/kg d.m. at fatigue. Whole blood and plasma NH3 did not change significantly during submaximal but both increased significantly during maximal exercise (P less than 0.001). During maximal exercise the leg released 7,120 mumol/min of lactate, whereas only 89 mumol/min of NH3 were released. NH3 accumulation in muscle could buffer only 3% of the hydrogen ions released from lactate, and NH3 release could account for only 1% of the net hydrogen ion transport out of the cell. Muscle glutamine was constant throughout the study, whereas glutamate decreased and alanine increased during exercise (P less than 0.001). No significant changes in either arterial whole blood glutamine or glutamate were observed. Arterial plasma glutamine and glutamate concentrations, however, increased and decreased (P less than 0.001), respectively, during exercise. It is concluded that (1) muscle and blood NH3 levels increase only during strenuous exercise and (2) NH3 accumulation is of minor importance for regulating acid-base balance in body fluids during exercise.
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PMID:Muscle ammonia and amino acid metabolism during dynamic exercise in man. 374 56

Fatigue--or decrease in force generation--is a reduction of simultaneously attached cross-bridges in the force generating state. Two processes are necessary for the force generation: Firstly Ca++ release from the sarcoplasmic reticulum to the sarcoplasm and the binding of Ca++ by the troponin molecule and secondly the turnover of myosin-actin cross-bridges. These processes require energy in at least three different ATPase reactions and can consequently be inhibited when ATP hydrolysis is decreased, i.e. when ATP content is to low or when the reaction products (ADP, Pi and H+) reach inhibiting levels or when muscle pH has decreased to values inhibiting actomyosin ATPase activity (22). Low pH will also decrease Ca++ release and Ca++ affinity by troponin (23). In isometric contraction the force is well preserved as long as ADP phosphorylation can be provided by both PCr degradation and anaerobic glycolysis. When the PCr store is exhausted the force starts to decline and if muscle activation is maintained the force will continue to decrease along with falling glycolytic rate. ADP phosphorylation rate decreases successively and ATP content falls with an at least transient increase in ADP. The ATP decrease, apart from the minor increase in ADP, is balanced by an equimolar increase in IMP. Lactate accumulation produces an increasing acidity with muscle pH values down to 6.25. Early changes in free ADP content cannot be excluded as reason for the initial decrease in force production followed by more pronounced inhibition of ATPase activity during continued contraction due to both substrate lack and product inhibition together with pH effect on the excitation--contraction mechanism. In dynamic exercise with supramaximum work intensity the relation between fatigue development and metabolism is similar. In prolonged dynamic exercise relying on oxidative metabolism without lactate formation the point of fatigue is reached when the glycogen store is exhausted. Again ADP phosphorylation rate is decreased when the energy substrate is changed from carbohydrate to fat with lower maximum rate of ATP resynthesis.
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PMID:Biochemistry of muscle fatigue. 396 54

The effects of endotoxin administration on glycolytic and tricarboxylic acid cycle intermediates in dog livers were studied. Changes in metabolite concentrations were expressed graphically as percentages of controls using "crossover" plots in order to identify transitory rate-controlling steps. The results show that endotoxin administration increased glycolytic flux through pyruvate kinase, inhibited gluconeogenic flux through phosphoenolpyruvate carboxykinase, decreased glycogen storage, shifted cytosolic and mitochondrial redox state from a relatively oxidized to a more reduced state, decreased the extra- and intramitochondrial malate-aspartate and glutamate-alpha-ketoglutarate shuttle activities, depleted ATP, ADP, and NADP concentrations, and decreased energy charge. Based on these data, it is concluded that pyruvate kinase plays the major role in the control of glycolysis, while phosphoenolpyruvate carboxykinase is the major controlling step for the regulation of gluconeogenesis in dog livers during endotoxic shock. In addition, the major factor in the regulation of metabolic pathways that produce and utilize high-energy phosphates in the livers was impaired in endotoxic shock.
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PMID:Glycolytic and tricarboxylic acid cycle intermediates in dog livers during endotoxic shock. 409 20

When n.m.r. is applied to suitable chosen biological problems it yields a wealth of fundamental information unmatched by any other technique. By means of 31P n.m.r. we have studied intact living muscle at rest, during contraction and during recovery from contraction. Phosphocreatine, ATP, inorganic phosphate, phosphorylated intermediaries of glycolysis, pH and the binding of Mg2+ to ATP are observed directly in the spectra. From the spectra can be calculated the concentration of free ADP, the free energy change of ATP hydrolysis, the production of lactic acid and the total ATP turnover. Changes in these quantities can thus be followed continuously in vivo and we have shown how they are related to the decline in force development and to the slowing of relaxation that occur during fatigue. Similar methods have been applied to study the control of glycolysis.
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PMID:Studies of the biochemistry of contracting and relaxing muscle by the use of 31P n.m.r. in conjunction with other techniques. 610 19

The absorption of light at 265 nm wave length in isolated muscle fibers and myofibrilles of vertebrate striated muscle was investigated with the aid of microscope with the wide spectral range (240--900 nm), equipped with image intensifier and recording cine camera. It was established that freshly isolated nonfatigue frog fibers absorbed UV-light along the entire of the length of the fiber. This fact attests the uniform distribution of ATP and some other nucleotides in the myoplasma of muscle cell. The fatigue of the fibers results in the appearance of a cross--striated pattern along the length of fiber, determinated by the alternation of the sarcomere regions with different degree of light absorption at the given wave length. The regions of the most heavily absorption of UV corresponds to the I-, M-, and N-bands of sarcomere. The comparison of the data obtained from intact and glycerinated fibers and also from myofibrilles with extracted A-bands allows to suppose that the absorption bands at 265 nm wave length are the places of location of bound ADP, RNA and minor fraction of ATP.
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PMID:[Location of adenine nucleotides in striated fibers of skeletal muscles]. 617 47

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