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

The changes of locomotor activities in rat loaded with swimming exercise were recorded by our newly devised apparatus. In addition, changes of lipid peroxide levels and their related enzyme activities in rat brain, liver as well as blood were studied. The results obtained were as follows: 1. The locomotor activities in rat recorded by the apparatus showed the same patterns as that reported by the other researchers. 2. After the loading of swimming, locomotor activities in rat during the dark period decreased significantly as compared to those of the control. 3. The levels of TBARS (thiobarbituric acid reactive substance), SOD (superoxide dismutase) and GSH-px (glutathione peroxidase) in rat liver elevated after the swimming exercise in the first group, which was sacrificed after loading with one treatment (about 5 hours) exercise of swimming. 4. The level of TBARS in rat brain elevated after the swimming exercise in the second group, which was sacrificed after loading with two treatment exercise of swimming. 5. The level of TBARS in plasma decreased, and GSH-px, GR (glutathione reductase) and catalase in red blood cells elevated in the third group, which was sacrificed after two-hour rest following the loading with two treatment exercise of swimming. It is indicated that our newly devised apparatus is useful for monitoring locomotor activities in rat, and that the fatigue in rat caused by swimming load can be shown in terms of changes in the above activities. The elevation of the level of TBARS during the swimming exercise observed in tissues of the brain and liver may suggest that the lipid peroxidation will reflect a certain state of fatigue in rat.
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PMID:[Changes of locomotor activities, lipid peroxide levels and their related enzyme activities in rat loaded with swimming exercise (author's transl)]. 727 88

Blood glutathione status and activities of antioxidant enzymes have been investigated during prolonged exercise with or without carbohydrate (CHO) supplementation. Eight subjects cycled at approximately 70% of maximal oxygen uptake to fatigue [134 +/- 19 (SE) min] on the first occasion (control, CON) and at the same work load and duration on the second occasion but with CHO ingestion during exercise. Blood reduced glutathione (GSH) concentration increased from 0.55 +/- 0.05 mM at rest to 0.77 +/- 0.09 mM after 120 min of exercise during CON (P < 0.01) but remained constant during CHO exercise. Blood glutathione disulfide (GSSG) levels were unchanged during CON and CHO exercise. Blood GSH + GSSG content and GSH/GSSG ratio were also significantly (P < 0.05) elevated during CON but not during CHO exercise. The increases in GSH and GSH + GSSG in CON were associated with decreases in plasma glucose and insulin levels. Activities of blood GSH peroxidase, GSSG reductase, and glucose-6-phosphate dehydrogenase were significantly increased during the CHO exercise, whereas only GSSG reductase activity was elevated during the CON ride. It is concluded that blood GSH increases during prolonged exercise and that CHO supplementation may prevent blood GSH increase possibly because of its inhibitory effects on hepatic hormonal releases, which stimulate GSH output.
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PMID:Blood glutathione status during exercise: effect of carbohydrate supplementation. 838 16

It is well known that physical training permits an animal to respond successfully to exercise loads of various types, intensities, and durations. Furthermore, the trained animal can sustain the activity for a long period before the fatigue becomes limiting. The effects of physical training on the antioxidant defenses of tissues and on their susceptibility to damage induced by exhaustive exercise have been investigated. Therefore, untrained rats were sacrificed either at rest or immediately after swimming to exhaustion. Rats trained to swim for 10 weeks were also sacrificed, 48 hr after the last exercise, either at rest or after exhaustive swimming. Homogenates of liver, heart, and muscle were used for biochemical determinations. Mitochondrial and sarcoplasmic (SR) or endoplasmic (ER) reticulum integrity was assessed with measurements of respiratory control index and latency of alkaline phosphatase activity. Lipid peroxidation was measured by determination of malondialdehyde and hydroperoxides. Additionally, the effect of training on the antioxidant protection systems of tissues was examined by determining the glutathione peroxidase and glutathione reductase activity and the overall antioxidant capacity. Mitochondrial, SR, and ER integrity and lipid peroxidation were similar in trained and untrained at rest animals, whereas the glutathione peroxidase and glutathione reductase activity and the overall antioxidant capacity of tissues were greater in trained animals. The exhaustive exercise gave rise to tissue damage irrespective of the trained state, as documented by similar loss of SR and ER integrity, and by increase in lipid peroxidation found in exhausted trained and untrained rats. Because exercise endurance capacity was greatly increased by training, our results suggest that free radical-induced damage in muscle could be one of the factors terminating muscle effort. In effect, the greater antioxidant level should allow trained muscle to withstand oxidative processes more effectively, thus lengthening the time required so that the cell function is sufficiently damaged as to make further exercise impossible.
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PMID:Antioxidants, tissue damage, and endurance in trained and untrained young male rats. 866 Jun 84

Little is known about the antioxidant capacity and oxidant-generating potential of newborn muscle, or how these properties compare with the adult and relate to fatigue resistance. We determined the 1) antioxidant enzyme activities [superoxide dismutase (SOD), catalase, glutathione peroxidase], 2) glutathione content, 3) oxidative capacity [indexed by succinic dehydrogenase activity], 4) extracellular cytochrome c reduction, and 5) efficacy of exogenously administered SOD in ameliorating fatigue in vitro of newborn and adult diaphragm (DIA). Newborn and adult DIA SOD activities were not different, whereas newborn catalase activity was greater, and newborn glutathione peroxidase activity and glutathione content less than adult DIA. Succinic dehydrogenase activity was approximately 2-fold greater in the adult compared with the neonate. Repetitive contractions led to a significant decline in newborn and adult DIA force; this decline was greater in the adult (78 +/- 4% decrement in force at 2 min) compared with newborn DIA (28 +/- 8% decrement in force at 2 min). Extracellular cytochrome c reduction was greater in adult as compared with newborn DIA during fatiguing contractions. Exogenous SOD attenuated fatigue in the adult, but had no effect on newborn DIA. We conclude that the oxidative capacity of the adult DIA is greater than that of the newborn and not matched by a concomitant increase in SOD activity. Our data suggest that the increased oxidative capacity relative to SOD activity in adult DIA may lead to oxidative stress and an enhanced susceptibility to fatigue.
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PMID:Rat diaphragm oxidative capacity, antioxidant enzymes, and fatigue: newborn versus adult. 921 38

We studied the effects of physical training on antioxidant defences and susceptibility to damage induced by exhaustive exercise in tissues of adult (12 mo) rats. Therefore, untrained animals were sacrificed either at rest (n = 8) or immediately after swimming to exhaustion (n = 8). Rats trained to swim for 10 weeks were also sacrificed, 48 hr after the last exercise, either at rest (n = 8) or after exhaustive swimming (n = 8). Integrity of mitochondria and sarcoplasmic (SR) or endoplasmic (ER) reticulum of liver, heart, and muscle was assessed by measuring mitochondrial respiratory control and latency of alkaline phosphatase activity. Lipid peroxidation was measured by determination of malondialdehyde and hydroperoxides. Additionally, the effect of training on tissue antioxidant systems was examined by determining the glutathione peroxidase (GPX) and glutathione reductase (GR) activity and the overall antioxidant capacity (CA). Membrane integrity was unaffected by training in liver and muscle, and improved in heart of at rest animals, whereas lipid peroxidation was reduced in both liver and heart. Glutathione peroxidase and glutathione reductase activity, and overall antioxidant capacity were increased (p < 0.05) by training in liver and muscle. In heart, antioxidant capacity was increased from 0.21+/-0.01 to 0.33+/-0.02 (p<0.05), but glutathione peroxidase activity remained unchanged (p>0.05), and glutathione reductase activity was decreased from 3.56+/-0.08 to 2.27+/-0.10 micromol x min(-1) x g(-1) (p < 0.05). The exhaustive exercise gave rise to tissue damage irrespective of trained state, as documented by similar loss of SR and ER integrity, and increase (p<0.05) in lipid peroxidation found in exhausted trained and untrained rats. However, the above changes were elicited by exercise of greater duration in trained than in untrained rats (340+/-17 min and 233+/-6 min, respectively). These findings support the view that free radical-induced damage in muscle could be one of the factors involved in muscle fatigue. If so, the increased endurance in trained rats should reflect lengthening of the time required for the oxidative processes to sufficiently impair cell functions so as to make further exercise impossible.
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PMID:Effect of training on antioxidant capacity, tissue damage, and endurance of adult male rats. 941 71

Diaphragmatic fatigue has been associated with increased production of reactive oxygen species. Among the defenses against reactive oxygen species is the glutathione redox system. The selenium-dependent enzyme glutathione peroxidase is an important component of this system. Thus, we hypothesized that selenium deficiency would lower glutathione peroxidase activity and render the diaphragm more susceptible to a mild exertional protocol. Sprague-Dawley rats were fed a selenium-deficient or control diet for 12 weeks then divided into four experimental groups: (1) unloaded, basic diet with selenium supplementation (control); (2) unloaded, selenium-deficient diet; (3) loaded, basic diet with selenium supplementation; and (4) loaded, selenium-deficient diet. Diaphragmatic in vitro contractile properties, glutathione peroxidase activity and glutathione content were measured. During inspiratory resistive loading, the animals breathed against an inspiratory resistor at 70% of maximal airway pressure until the target pressure was not achieved for five consecutive breaths. Selenium deficiency resulted in a significant decrease in diaphragmatic glutathione peroxidase activity, without changes in total glutathione content. Neither selenium deficiency nor inspiratory resistive loading alone impaired diaphragmatic contractility. Selenium deficiency in conjunction with inspiratory resistive loading resulted in a significant decrease in diaphragmatic twitch and tetanic force, with a downward shift in the force/frequency curve. These data suggest that selenium deficiency lowers diaphragmatic glutathione peroxidase activity, and when these animals are subjected to the oxidative stress of resistive loading, there is an impairment in muscle function. We conclude that a functional glutathione peroxidase is necessary to protect the diaphragm against the effects of resistive loading.
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PMID:Effects of selenium deficiency on diaphragmatic function after resistive loading. 955 Feb 26

Muscular exercise results in an increased production of radicals and other forms of reactive oxygen species. Further more, growing evidence implicates cytotoxic ROS as an underlying cause in exercise-induced disturbances in muscle redox status that could result in muscle fatigue or injury. Muscle cells contain complex cellular defense mechanisms to minimize the risk for oxidative injury. Two major classes of endogenous protective mechanisms work together to reduce the harmful effects of oxidants in the cell: (1) enzymatic and (2) nonenzymatic antioxidants. Key antioxidant enzymes include superoxide dismutase, glutathione peroxidase, and catalase. These enzymes are responsible for removing superoxide radicals, hydrogen peroxide or organic hydroperoxides, and hydrogen peroxide, respectively. Important nonenzymatic antioxidants include vitamins E and C, beta-carotene, GSH, uric acid, ubiquinone, and bilirubin. Vitamin E, beta-carotene, and ubiquinone are located in lipid regions of the cell, whereas uric acid, GSH, and bilirubin are in aqueous compartments of the cell. Although numerous animal experiments have demonstrated that the addition of antioxidants can improve muscular performance, to date, limited evidence shows that dietary supplementation with antioxidants improves human performance. This is an important area for future research.
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PMID:Antioxidants and exercise. 1041 Aug 39

Cellular oxidants include a variety of reactive oxygen, nitrogen, and chlorinating species. It is well established that the increase in metabolic rate in skeletal muscle during contractile activity results in an increased production of oxidants. Failure to remove these oxidants during exercise can result in significant oxidative damage of cellular biomolecules. Fortunately, regular endurance exercise results in adaptations in the skeletal muscle antioxidant capacity, which protects myocytes against the deleterious effects of oxidants and prevents extensive cellular damage. This review discusses the effects of chronic exercise on the up-regulation of both antioxidant enzymes and the glutathione antioxidant defense system. Primary antioxidant enzymes superoxide dismutase, glutathione peroxidase, and catalase will be discussed as well as glutathione, which is an important nonenzymatic antioxidant. Growing evidence indicates that exercise training results in an elevation in the activities of both superoxide dismutase and glutathione peroxidase along with increased cellular concentrations of glutathione in skeletal muscles. It seems plausible that increased cellular concentrations of these antioxidants will reduce the risk of cellular injury, improve performance, and delay muscle fatigue.
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PMID:Exercise training-induced alterations in skeletal muscle antioxidant capacity: a brief review. 1041 60

The suggested role of oxidative stress in the pathogenesis of heart failure is largely based on utilizing left heart failure models. The present study on rats evaluated changes in antioxidants as well as oxidative stress in relation to hemodynamic function subsequent to the right heart failure induced by monocrotaline (50 mg/kg, i.p.). During the post-injection period, monocrotaline (MCT)-treated rats demonstrated a persistent growth depression. Two to three weeks after the injection, MCT-treated rats showed signs of fatigue, peripheral cyanosis and dyspnea. In these rats, right heart hypertrophy was confirmed by a significant increase in right ventricular weight as well as right ventricle to body weight ratio. In MCT-treated rats, there was also a significant increase in right ventricular systolic as well as end diastolic pressures. No change in lung and liver wet/dry weight ratios between MCT-treated and control animals was observed. Based on the hemodynamic data as well as other clinical observations, the functional stage achieved was compensated heart failure. Myocardial antioxidant enzymes, catalase, glutathione peroxidase and superoxide dismutase, in the MCT-treated rats were not different compared to control rats. Vitamin E levels were significantly depressed in the RV and there was no change in retinol levels. There was a significant increase in lipid hydroperoxide concentrations in MCT-treated rats as compared to the control group. These data provide evidence that right heart failure is associated with an increase in oxidative stress.
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PMID:Myocardial oxidative stress changes during compensated right heart failure in rats. 1044 2

Muscular exercise results in an increased production of radicals and other forms of reactive oxygen species (ROS). Recent evidence suggests that radicals and other ROS are an underlying aetiology in exercise-induced disturbances in muscle redox status. These exercise-induced redox disturbances in skeletal muscle are postulated to contribute to both muscle fatigue and/or exercise-induced muscle injury. To defend against ROS, muscle cells contain complex cellular defence mechanisms to reduce the risk of oxidative injury. Two major classes (enzymic and non-enzymic) of endogenous protective mechanisms work together to reduce the harmful effects of oxidants in the cell. Primary antioxidant enzymes include superoxide dismutase (EC 1.15.1.1; SOD), GSH peroxidase (EC 1.11.1.9; GPX), and catalase (EC 1.11.1.6); these enzymes are responsible for removing superoxide radicals, H2O2 and organic hydroperoxides, and H2O2 respectively. Important non-enzymic antioxidants include vitamins E and C, beta-carotene, GSH and ubiquinones. Vitamin E, beta-carotene and ubiquinone are located in lipid regions of the cell, whereas GSH and vitamin C are in aqueous compartments of the cell. Regular endurance training promotes an increase in both total SOD and GPX activity in actively-recruited skeletal muscles. High-intensity exercise training has been shown to be generally superior to low-intensity exercise in the upregulation of muscle SOD and GPX activities. Also, training-induced upregulation of antioxidant enzymes is limited to highly-oxidative skeletal muscles. The effects of endurance training on non-enzymic antioxidants remain a relatively uninvestigated area.
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PMID:Analysis of cellular responses to free radicals: focus on exercise and skeletal muscle. 1081 71


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