UMLS:C0015672 - FACTA Search

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Query: UMLS:C0015672 (fatigue)
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Free radical activation and lipid peroxidation have been described in skeletal muscle during strenuous exercise. We hypothesized that oxygen radicals could also be formed in the diaphragm muscle during strenuous resistive breathing and that these radicals might affect diaphragm function. Seven control and 12 experimental male Sprague-Dawley rats were studied. Six experimental animals were subjected to resistive breathing (RB) alone and six animals received 15 min of mechanical ventilatory support (MV) after the resistive breathing period. Inspiratory resistance was adjusted to maintain airway opening pressure at 70% maximum in both groups until exhaustion. Diaphragm samples were obtained for analysis of thiobarbituric acid-reactive substances (TBAR), reduced glutathione (GSH), and glutathione disulfide (GSSG). In vitro isometric contraction times, twitch (Pt) tension and maximum tetanic (Po) tension, force-frequency curves, fatigue index, and recovery index were measured. In RB and MV compared with controls, there were significant decreases in Pt and Po. Diaphragm TBAR concentrations were increased in MV compared with controls or RB. GSSG-to-total glutathione ratio was increased in RB and MV compared with controls. Production of free radicals during RB and MV may represent an important mechanism of diaphragmatic injury that could contribute to the decline in contractility.
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PMID:Resistive breathing activates the glutathione redox cycle and impairs performance of rat diaphragm. 155 28

Eight men cycled for about 6 minutes at workloads corresponding to 44 and 72% of maximal oxygen uptake and to fatigue at 98% maximal oxygen uptake. Blood samples from a brachial artery and a femoral vein were taken at rest and during exercise. Hypoxanthine, xanthine and urate in plasma were significantly elevated at fatigue and after 10 minutes of recovery. Only hypoxanthine showed a significant arterio-femoral venous difference. The release of hypoxanthine from the legs increased during the recovery period and was three-fold higher 10 minutes post exercise than at the end of exercise. It is concluded that the marked increase in plasma hypoxanthine which occurs during intensive exercise originates from the working muscle whereas the transformation to xanthine and urate may occur in other tissues. Glutathione, methemoglobin and malondialdehyd (MDA) were used as plasma markers of free radicals. Total glutathione (glutathione + glutathionedisulfide) in blood and plasma increased during intensive exercise and may be indicative of free radical formation. However, MDA was not detectable in plasma during any conditions (less than 0.1 mumol x l-1 plasma) and methemoglobin decreased slightly during exercise. Further studies using more specific techniques are required to determine whether the formation of free radicals is increased after brief intensive exercise.
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PMID:Changes in plasma hypoxanthine and free radical markers during exercise in man. 187 76

Many data suggest an involvement of toxic oxygen radicals in the termination of endurance to muscle fatigue. Being reduced glutathione (GSH), an efficient intracellular physiological antioxidant, experiments have been performed to discover whether exogenous GSH modifies endurance to exhaustive swimming in mice. GSH was administered to mice as a single dose (250, 500, 750 or 1000 mg/kg i.p.) or as repeated doses (250 mg/kg i.p. once a day during 7 days) 10 min before a swimming test to exhaustion. GSH 500, 750 and 1000 mg/kg, increased endurance to swimming by respectively 102.4%, 120.0% and 140.7%. GSH 250 mg/kg did not affect endurance when injected in a single dose but increased it by 103.7% when injected once a day for 7 days.
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PMID:Exogenous glutathione increases endurance to muscle effort in mice. 206 90

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

Recent work has shown that loaded breathing produces alterations in diaphragmatic glutathione metabolism. Moreover, it has been suggested that alterations in glutathione levels may be related to the development of respiratory muscle fatigue and respiratory failure during loading. The purpose of this study was to determine whether it was possible to augment diaphragmatic stores of reduced glutathione (GSH) and thereby delay the development of respiratory failure during loaded breathing by administering N-acetylcysteine (NAC), a glutathione precursor. We compared the effects of massive inspiratory loading on saline- and NAC-treated groups of decerebrate unanesthetized rats with loading continuing until respiratory arrest occurred. As controls, we also studied unloaded saline- and NAC-treated animals. After arrest, diaphragms were excised, measurement was made of diaphragmatic GSH and oxidized glutathione (GSSG) concentrations, and assessment was made of in vitro diaphragmatic contractility (i.e., the force-frequency relationship and in vitro fatigability). We found that loading of saline-treated animals produced reductions in the diaphragmatic force-frequency curve, reductions in GSH, and increases in GSSG levels. NAC administration blunted loading-induced decreases in diaphragmatic GSH levels and reduced the in vitro fatigability of excised diaphragm muscle strips. NAC did not significantly alter the time to respiratory arrest, however, and also failed to alter the effect of loaded breathing on the diaphragmatic force-frequency relationship. These findings suggest that free radical-mediated GSH depletion is not the limiting factor determining the development of respiratory failure in this model of loaded breathing.
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PMID:N-acetylcysteine administration and loaded breathing. 755 41

Some studies have suggested that protective mechanisms downregulate diaphragm activity during loaded breathing so as to prevent respiratory-muscle fatigue. Other work has indicated, however, that loading can sometimes elicit significant diaphragmatic fatigue, and that the development of fatigue may be related to alterations in diaphragmatic glutathione concentrations. One potential explanation for these discrepant observations is that the mechanism of respiratory failure may vary as a function of load magnitude, and that some loads evoke little fatigue whereas others produce substantial fatigue and glutathione alterations. The purpose of this study was to examine this issue by determining the diaphragmatic fatigue and alterations in glutathione concentrations produced by a range of inspiratory resistive loads. Experiments were performed on decerebrate rats divided into a control, unloaded group and a group loaded with small, medium, and large inspiratory resistive loads that were applied until respiratory failure occurred. After respiratory arrest, the animals' diaphragms were excised, an in vitro determination was done of diaphragm contractility characteristics, and samples of muscle were assayed for GSH (reduced glutathione) and GSSG (oxidized glutathione). We found that in vitro diaphragm force generation was severely reduced for loaded breathing, and surprisingly, that the magnitude of the low-frequency fatigue present was similar in the three loaded groups. Reductions in diaphragmatic GSH levels and increases in GSSG levels were found in all three loaded groups. Reductions in diaphragmatic GSH levels and increases in GSSG levels were found in all three loaded groups, but again, the magnitude of these changes were similar.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effect of varying load magnitude on diaphragmatic glutathione metabolism during loaded breathing. 758 8

Recent studies have suggested that loaded breathing elicits alterations in diaphragmatic glutathione levels that may be mediated by free radicals and may also be linked to the development of diaphragm fatigue. While free-radical generation in a number of pathophysiologic conditions is known to be a function of ambient oxygen concentrations, the effect of varying inspired oxygen concentration on the diaphragmatic response to loaded breathing (i.e., on diaphragm fatigue and glutathione levels) has not been studied. In this study, we compared the effect of loaded breathing, continued until respiratory arrest in decerebrate rats breathing room air (RA), with the effect of the same load on animals breathing 100% oxygen (O2). After arrest, the animals' diaphragms were excised, force generation was assessed in vitro, and diaphragmatic levels of reduced glutathione (GSH) and oxidized glutathione (GSSG) were determined. Similar measurements were made on unloaded control animals. We found both similarities and differences in the response to loading in O2- and RA-breathing animals. O2-breathing loaded animals had a greater load endurance, lower blood pressure at the end of loading, higher carbon dioxide levels, and greater high-frequency fatigue at the conclusion of loaded trials than did RA-breathing animals. The degree of low-frequency fatigue was similar, however, in the O2- and RA-breathing loaded groups (i.e, twitch force averaged 7.9 +/- 0.6, 8.4 +/- 0.5, 3.8 +/- 0.9, and 4.5 +/- 0.8 N/cm2, respectively, in the RA/unloaded, O2/unloaded, RA/loaded, and O2/loaded groups, p < 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effect of varying inspired oxygen concentration on diaphragm glutathione metabolism during loaded breathing. 758 7

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

The effects of vitamin E deficiency on diaphragm function were studied at rest and after resistive breathing (RB) in Sprague-Dawley rats (wt 300-400 g). The animals were pair fed a vitamin E-deficient diet (E-def) or a matched vitamin E-sufficient diet (E-suf). Each diet group was then further subdivided into a group that breathed unimpeded (control) and a second group that breathed through an inspiratory resistor until the animals were unable to sustain 70% of their maximum airway pressure. Diaphragm samples were obtained for analysis of thiobarbituric acid-reactive substances, glutathione (GSH) concentrations, and glutathione disulfide (GSSG) concentrations. In vitro isometric contractile studies were also performed and included twitch (Pt) and maximum tetanic (Po) tensions, force-frequency curves, fatigue index, and recovery index. Pt was significantly reduced in the E-suf RB group as well as both of the E-def groups. Po was also significantly reduced in both E-def groups. The E-def rats subjected to RB showed a significant decrease in tension at both high and low frequencies compared with the E-suf rats. Concentrations of diaphragm thiobarbituric acid-reactive substances were significantly increased in both E-def groups. RB in both E-suf and E-def rats resulted in increases in diaphragm concentrations of GSSG and decreases in the GSH/GSSG ratios. We conclude that reduction of contractile function, lipid peroxidation, and activation of the GSH redox cycle occur with RB and that these effects are significantly increased in the presence of vitamin E deficiency.
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PMID:Diaphragmatic function after resistive breathing in vitamin E-deficient rats. 844 2

Based on recent studies, it has been suggested that free radicals are elaborated in the respiratory muscles during strenuous contractions and contribute to the development of muscle fatigue. If this theory is correct, then it should be possible to attenuate the development of diaphragm fatigue and/or delay the onset of respiratory failure during loaded breathing by administering a free radical scavenger. The purpose of the present experiment was, therefore, to examine the effect of N-acetylcysteine (NAC), a free radical scavenger and glutathione precursor, on the evolution of respiratory failure in decerebrate unanesthetized rats breathing against a large inspiratory resistive load. We compared the inspiratory volume and pressure generation over time in animals pretreated with either saline or NAC (150 mg/kg) and then loaded until respiratory arrest. After arrest, the diaphragm was excised, and samples were assayed for reduced (GSH) and oxidized glutathione. As a control, we also assessed respiratory function and glutathione concentrations in groups of nonloaded saline- and NAC-treated animals. We found that NAC-treated animals were able to tolerate loading better than the saline-treated group, maintaining higher inspiratory pressures and sustaining higher inspired volumes. Administration of NAC also increased the time that animals could tolerate loading before the development of respiratory arrest. In addition, although saline-treated loaded animals had significant reductions in diaphragmatic GSH levels compared with unloaded controls, the magnitude of this reduction was blunted by NAC administration (i.e., GSH averaged 965 +/- 113, 568 +/- 83, 907 +/- 39, and 784 +/- 61 nmol/g for unloaded-saline, loaded-saline, unloaded-NAC, and loaded-NAC groups, P < 0.05, with the value for the loaded-saline group lower than the values for the two unloaded groups; GSH for the loaded-NAC group was not different, however, from unloaded controls). These data demonstrate that administration of NAC, a free radical scavenger, slows the rate of development of respiratory failure during inspiratory resistive loading.
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PMID:N-acetylcysteine administration alters the response to inspiratory loading in oxygen-supplemented rats. 910 48

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