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)

Muscle fatigue is accompanied by a series of biochemical correlations as substrate depletion, lactate accumulation, shifts of pH, increase of phosphate (Pi), arise of free radicals or disturbances of ionic balances. In last time high interest has been directed to the increase of extracellular potassium during extensive muscle activity. It was suggested that high K+ concentration in the interstitium may alter propagation of action potential along the T-tubules or induces membrane depolarization with physiological consequences. In order to elucidate the role of potassium accumulation, experiments were performed on isolated rat muscles. An elevation from 5 to 10 mmol K+ of the bath solution causes a significant decrease of the conduction velocity of the action potential. This effect is more pronounced on fatigue-sensitive fast twitch EDL muscles than on fatigue-resistant slow twitch SOL muscles. Moreover, after tetanic stimulations of these muscles in normal solution, the conduction velocity dropped by the same amount as in high K+ solution but, again, differently in both muscle types. Therefore it is supposed that K+ accumulation during intensive muscle activity contributes to fatigue.
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PMID:[Problems of muscular fatigue--relationship to stimulation conduction velocity and K(+) concentration]. 239 48

Magnetic resonance imaging (MRI) is superior to ultrasonography and X-CT especially in density resolution in soft tissue. 31P NMR provides information on metabolism, which has not been obtained in vivo by conventional methods, such as phosphocreatine (PCr), inorganic phosphate (Pi), ATP, and intracellular pH. We used MRI and 31P NMR spectroscopy to study skeletal muscle metabolism of human and rat. These NMR results suggested that 1) estimation of muscle fiber composition, 2) evaluation of muscle ATP turnover and 3) imaging of local muscle fatigue are possible.
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PMID:Evaluation of exercise muscle energetics by NMR. 240 Apr 64

The protective effect of calcium antagonists on ischemic heart has been attributed to decreased energy expenditure. We administered one of the newer calcium antagonists, DL-bepridil (0.1-10 microM), to Langendorff rat hearts 10 or 15 min before ischemia (flow reduction approximately 80%). Vasodilation during normoxia was already observed with 0.3 microM DL-bepridil (flow increase 34%, p less than 0.005). This concentration decreased normoxic contractility and ischemic purine release, a marker for ATP breakdown. In the absence of bepridil, purine release of hearts that were made ischemic was 8.5-fold higher than that of normoxic control hearts. With 1 microM bepridil, the ischemic purine efflux was suppressed by 55% (p less than 0.05), with negative inotropy (p greater than 0.05) during normoxia. At 3 and 10 microM, bepridil decreased normoxic contractility by 40 and 75%, respectively (p less than 0.001), concomitant with a decrease in ischemic purine release by 80 and 76%, respectively (p less than 0.01). At the end of ischemia, myocardial ATP and creatine phosphate had decreased by 22 and 55%, respectively (p less than 0.05), and ADP, AMP, and creatine had increased 1.5-3.5-fold (p less than 0.05). Bepridil (3 microM) normalized the adenine nucleotide values; creatine and creatine phosphate approached control levels. The dose-dependent protection of the ischemic heart by bepridil appears to arise from its negative inotropic action during normoxia.
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PMID:Protection by bepridil against myocardial ATP-catabolism is probably due to negative inotropy. 244 Nov 54

By the use of invasive techniques, skeletal muscle has been shown to contribute to thermogenesis induced by glucose in humans. In an attempt to study this phenomenon by a non-invasive method, this study investigated intracellular high-energy phosphorous compounds in calf muscle by 31P MR spectroscopy during an oral glucose load in healthy lean subjects. The inorganic phosphate concentration increased gradually (P less than 0.05) after glucose intake. The phosphocreatine/inorganic phosphate rate decreased (P less than 0.05) and the estimated ADP concentration increased. ATP and intracellular pH remained unchanged after the glucose administration. No changes were seen in the control experiments. The processes responsible for the decreased energy state of the skeletal muscle cell may be an obligatory conversion of glucose to glycogen. Also, facultative processes, such as sodium/potassium pumping and substrate cycles stimulated by the sympatho-adrenal system, may be partly responsible.
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PMID:Changes of high-energy phosphorous compounds in skeletal muscle during glucose-induced thermogenesis in man. A 31P MR spectroscopy study. 259 28

1. Maximal calcium-activated force (Fmax) and calcium sensitivity were markedly decreased in detergent-skinned fibres from skeletal and cardiac muscle by solutions that mimicked the total milieu changes associated with fatigue and hypoxia. Further experiments determined the relative contribution of each of the individual changes in milieu. 2. Both Ca2+ sensitivity and Fmax of skeletal and cardiac fibres were decreased with increased [H+] or inorganic phosphate (Pi). These effects were greater in cardiac muscle. 3. Decreasing MgATP over the range observed with fatigue and hypoxia (6.8-4.7 mM) had no effect on Fmax or Ca2+ sensitivity of either muscle type. 4. Decreasing phosphocreatine (PCr: 15-1 mM) increased Fmax but had little effect on Ca2+ sensitivity in both muscle types. In cardiac fibres, the effect on Fmax could be mimicked by inhibition of endogenous creatine kinase. 5. ADP (0.7 mM) increased Fmax and Ca2+ sensitivity, while AMP (0.06 mM) slightly increased Fmax but had no effect on Ca2+ sensitivity of either skeletal or cardiac fibres. 6. Creatine (25 mM) had no significant effect on either Ca2+ sensitivity or Fmax of skeletal and cardiac muscle fibres. At higher levels (50 mM), however, creatine depressed Fmax and slightly altered Ca2+ sensitivity. 7. Thiophosphorylation of myosin P light chains (phosphorylatable light chains of myosin) in rabbit psoas fibres had no effect on Ca2+ sensitivity, yet slightly but significantly increased Fmax under fatigue conditions. 8. Reducing the affinity for ATP hydrolysis (by adding ADP, AMP and creatine) over the range calculated for fatigue/hypoxia (60-45 kJ/mol) produced the enhancement in Fmax expected from added ADP and AMP in cardiac but not skeletal muscle, indicating that changes in affinity influence Fmax of skeletal muscle. Reducing affinity produced little change in Ca2+ sensitivity of skeletal muscle. In contrast, the change produced in cardiac muscle was greater than that expected from addition of ADP and AMP; i.e. decreasing affinity increases calcium sensitivity of the heart. 9. Simple summation of all significant changes expected from each constituent altered by fatigue/hypoxia adequately predicted the observed changes in Fmax and Ca2+ sensitivity in both cardiac and skeletal muscle fibres with but one exception (the change in Ca2+ sensitivity of skeletal muscle at pH 7 was slightly overestimated).
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PMID:Changes of intracellular milieu with fatigue or hypoxia depress contraction of skinned rabbit skeletal and cardiac muscle. 260 Aug 30

Neurological symptoms including lethargy, obtundation, and confusion are early and common findings in patients with sepsis. The etiology of the mental status changes that occur during severe infection is not known. We investigated the effects of sepsis on the levels of high-energy phosphates to determine whether decreased energy metabolism was a factor in the depressed neurological state. The time course of changes in brain pH and brain high-energy phosphate metabolites during an Escherichia coli infusion was determined from sequential phosphorus-31 nuclear magnetic resonance (31P-NMR) spectra of ketamine-xylazine-anesthetized rats. A second group of rats received 0.9% saline infusion and served as a control group. Despite severe obtundation and near loss of righting reflex, the rats in the septic group had no significant differences in the brain pH, the ratio of phosphocreatine (PCr) to beta-adenosine 5'-triphosphate (beta-ATP), or in the ratio of PCr to Pi. The only significant decrease in brain high-energy phosphates or pH occurred terminally in the septic rat group and corresponded with a rapidly falling arterial blood pressure. We conclude that the severe neurological depression that is characteristic of sepsis is not due to decreased levels of brain high-energy phosphates or brain acidosis.
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PMID:An in vivo examination of rat brain during sepsis with 31P-NMR spectroscopy. 261 Feb 45

1. The relationship between intracellular metabolites and the generation of force during fatigue has been examined in the first dorsal interosseous muscle of the hand. With the arm made ischaemic, the muscle was fatigued by three bouts of maximal voluntary contraction, leaving approximately three minutes ischaemic rest between contractions. During one series of experiments intracellular phosphorus metabolites were measured by nuclear magnetic resonance during the intervals between the fatiguing contractions: in the second series contractile properties were tested with brief electrical stimulation during the rest intervals. 2. The relationships between loss of force and change in metabolite concentrations obtained with four normal subjects were compared with those from one subject with myophosphorylase deficiency (MPD) who could not utilize muscle glycogen and therefore produced no hydrogen ion from glycolysis during exercise. 3. For both the MPD and normal subjects the relationship between relative force loss and inorganic phosphate (Pi) concentration was curvilinear, force changing little in the early stages of the contraction when the intracellular Pi was accumulating rapidly but falling faster when the Pi was above 25 mM and increasing relatively slowly. 4. In the normal subjects intracellular pH fell from a mean of 7.03 +/- 0.01 (mean +/- S.E. of mean, n = 19) in the fresh muscle to 6.51 +/- 0.02 at the end of the fatiguing exercise; force, as a percentage of the initial value, fell in proportion to the increase in H+ concentration. In the MPD subject pH did not change and force loss was therefore independent of H+ accumulation. In the normal subjects the force of the fatiguing muscle showed an approximately linear relationship with the concentration of the monobasic form of inorganic phosphate. However, the MPD subject showed a quite different relationship, with force loss being much greater for a given concentration of monobasic phosphate. This result indicates that monobasic phosphate is not a unique determinant of force loss in fatigued muscle. 5. During the first 60 s of recovery in the normal subjects, pH remained low while force recovered, indicating a mechanism of force loss that was independent of H+ accumulation. However, the recovery of force was not complete, so that for comparable phosphocreatine contents the recovering, more acid, muscle generated less force than the muscle that was being fatigued. It was estimated that H(+)-dependent and independent mechanisms contributed roughly equally to the observed force loss. The relationship between force and the concentration of monobasic phosphate differed in fatiguing and recovering muscle.
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PMID:Changes in force and intracellular metabolites during fatigue of human skeletal muscle. 262 21

Threshold load tests have shown that the fatigue strength of Class I composite fillings may be increased up to 150 N by the application of a base material. This effect varied only with the consistency of the composite, not with the type of base material used. However, differences were found in the depths at which losses of marginal adaptation occurred: where glass ionomer cement base (polyalkenoate) was used, marginal leakage demonstrated by pigment penetration tests stopped at the interface between filling and base, while in those cases where phosphate cement was used as base material, pigment penetration was shown to extend down to the floor of the cavity. Mesiodistal sections through Class II MOD restorations with the same combinations of materials after 24 hours of storage in pigment solutions and without loading revealed that a close marginal fit in the area of the cervical step can be obtained with the use of glass ionomer cement as base material. In contrast to this observation the use of phosphate cement as base material is associated with marginal leakage down to the area of the floor of the cavity in about one half of the restorations.
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PMID:[Fatigue strength and marginal adaptation of composite fillings]. 263 40

Muscular fatigue is of critical importance to performance and as such has been the subject of numerous investigations. However, a clear cause remains elusive. Although many factors have been identified, this review deals only with those which occur distal to the neuromuscular junction. Factors discussed include: energy supply (ATP/creatine phosphate, glycogen, oxygen, and free fatty acids); the accumulation of metabolites (lactate/hydrogen ions, calcium, ammonium, electrolyte and water shifts); and, the special case of eccentric work. The results of many studies using various methodologies are examined. Peripheral fatigue appears to be a complex series of interactions with variable influence on the development of fatigue depending upon the nature of the work performed.
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PMID:Biochemical aspects of peripheral muscle fatigue. A review. 264 71

Recent work has now clearly established that coronary arterial thrombosis is the direct cause of acute myocardial infarction. This thrombotic event occurs when a pre-existing atherosclerotic plaque ruptures or fissures, thereby exposing underlying thrombogenic material to the circulation. Platelets are thus activated and the clotting cascade is initiated. It is as yet unclear why a previously stable atherosclerotic plaque should fissure or rupture. However, suggested mechanisms include release of vasoactive substances from activated platelets, coronary arterial vasomotion, mechanical stress fatigue of the atherosclerotic plaque, and rupture of vasa vasorum within the atherosclerotic plaque. The resultant cessation of myocardial blood flow produces specific biochemical and physiological alterations secondary to myocardial ischemia. Intracellular acidosis, loss of high-energy phosphates, reduced sensitivity of contractile proteins to calcium, and accumulation of inorganic phosphate and lipid, all occur within the ischemic myocyte. Diastolic compliance is markedly reduced by ischemia followed by cessation of systolic contractile activity. Most of these alterations are reversible if ischemia is relieved promptly. Prolonged ischemia leads to delayed biochemical and physiological recovery and/or cell necrosis.
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PMID:The pathophysiology of acute myocardial infarction. 266 57

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