UMLS:C0022116 - FACTA Search

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Query: UMLS:C0022116 (ischemia)
91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The activities of Superoxide Dismutase (SOD), Glutathione Peroxidase (GSH-Px) and Catalase (CAT) in the ischemic cerebral tissue following the unilateral middle cerebral artery occlusion of rats were assessed. In comparison with the sham-operated rats, both SOD and GSH-Px activity in the ischemic area (striatum and fronto-parietal cortex) were significantly reduced by 30 min. of ischemia, GSH-Px activity in the peri-ischemic area (parieto-parasagittal) was significantly reduced as well. It was shown that in the striatum the GSH-Px activity was much higher than that in the cortex. According to our data, it was suggested that in the ischemic condition, cerebral Superoxide (O2-) and Hydrogen Peroxide (H2O2) were accumulated, and thus the polyunsaturated fatty acids in the neuronal membrane were trapped by these free radical. And such a process resulted in neuronal damage. It implicated that the oxygen free radical might be involved in the neuronal damage induced by Dopamine, since the O2- and H2O2 were excessively generated during the oxidative deamination of Dopamine and the free radical scavengers, SOD and GSH-Px were decreased concomitantly in the cerebral ischemic tissue.
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PMID:[A study on the activity of three antioxidant enzymes in the brain of experimental acute cerebral ischemia]. 130 99

Lipid peroxidation disrupts membrane integrity and causes structural and functional alterations in ischemic tissues. Taurine and ketamine are putative ischemic protectants that affect Ca2+ influx. Here we report the influence of these compounds on lipid peroxidation in subcellular fractions, isolated cells and intact tissue from bovine retinas. P2 membrane fractions and isolated cells were exposed to the lipid peroxidation inducers cadmium chloride (200 microM) or L-ascorbic acid (1 mM) in the presence of 0-50 mM taurine, 0-10 mM ketamine, 1 mM kynurenic acid or 1 mM dextromethorphan. The latter compounds are N-methyl-D-aspartate receptor antagonists. Lipid peroxidation in isolated eyes reperfused after 1 h of ischemia either with or without protectants was determined by thiobarbituric acid assay. Glutathione was measured in isolated retinas subjected in vitro to simulated ischemia (no glucose or oxygenation) for 60 min either alone or in the presence of taurine or ketamine. Ketamine inhibited chemical- or ischemia-induced lipid peroxidation as well as ischemic glutathione depletion. Under the same conditions, taurine failed to affect lipid peroxidation or glutathione. The data show a direct effect of ketamine on lipid peroxidation and point to separate mechanisms of action for ketamine and taurine.
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PMID:Effects of taurine and ketamine on bovine retinal membrane lipid peroxidation. 183 70

Glutathione status and products from lipid peroxidation [measured as thiobarbituric acid reactive substances (TBARS)] were determined in red and white muscle tissue of the rat. Marked differences between both muscle types were found in reduced glutathione (GSH) and oxidized glutathione (GSSG) content, exhibiting 163% and 183%, respectively, higher levels in red than in white muscle tissue, while the ratio of GSSG/GSH showed no differences. These characteristics may be due to an adaptive mechanism related to the 48% higher baseline level of TBARS in red muscle tissue. Immediately after 4 h of tourniquet-ischemia GSH, GSSG, and TBARS were increased (16%, 32%, 45% in white muscle; 19%, 49%, and 42% in red muscle, respectively), whereas the GSSG/GSH ratio remained unchanged. During the subsequent reperfusion period, GSH decreased within 2 h by 39% in white and 89% in red muscle to a minimal level of 5 mmol/g protein in both types of muscle. No recovery from the depletion was observed up to 12 h of reperfusion. The GSH decrease was parallelled by a marked increase of the GSSG/GSH ratio (150% in white and 450% in red muscle) and followed by about 150% increase in TBARS in both muscle types. This suggests that the increase in damaging TBARS is a secondary event after depletion of cellular antioxidants. Treatment of the animals during the reperfusion period with methyl-prednisolone, deferoxamine, or superoxide dismutase and catalase did not prevent the GSH decrease, but were effective in reducing the GSSG/GSH ratio to near normal and reducing the TBARS increase by about 50%.
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PMID:Differences in glutathione status and lipid peroxidation of red and white muscles: alterations following ischemia and reperfusion. 192 69

Neutrophil-related, oxidant-mediated injury to the pulmonary microvasculature appears to follow endotoxemia, cutaneous thermal injury, and ischemia-reperfusion injury to the liver or intestine. Glutathione is an important endogenous intracellular oxygen radical scavenger. Plasma concentrations of oxidized glutathione (GSSG) reflect oxidant injury resulting from an overdose of certain oxidatively metabolized drugs. The purpose of this investigation was to evaluate plasma GSSG as an indicator of oxidant stress resulting from activation of the endogenous inflammatory response. An established model of neutrophil- and oxidant-related acute lung injury following intestinal ischemia and reperfusion in rats was used. Intestinal ischemia was induced by clip occlusion of the superior mesenteric artery (SMA) for 120 min. Reperfusion resulted from SMA clip removal. Following reperfusion for 0, 15, or 120 min, plasma GSSG levels in portal vein, inferior vena cava (IVC), and aorta were obtained. Plasma GSSG was undetectable in sham animals and those with intestinal ischemia alone. Following reperfusion, all plasma samples had significant elevations in GSSG. Aortic plasma GSSG after 15 min of reperfusion was significantly elevated compared to both portal vein and IVC plasma GSSG. These data suggest that oxidant stress after intestinal reperfusion is reflected by elevations in plasma GSSG. The step up in plasma GSSG across the pulmonary vascular bed, a site of known oxidant injury, suggests that plasma GSSG may be a useful marker of oxidant stress in vivo, particularly with regard to the pulmonary microvasculature. This simple in vivo approach to assessing oxidant stress related to inflammatory tissue injury may have the potential to be of significant use in the clinical setting.
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PMID:Arterial levels of oxidized glutathione (GSSG) reflect oxidant stress in vivo. 233 13

Reperfusion after ischemia produces tissue injury due to free radicals generated during the reflow period. Glutathione (GSH) mediates against this oxidant damage by scavenging free radicals and protecting cells against injury. In an attempt to reduce the injury caused by free radicals, rat kidneys were pretreated with GSH monoethyl ester to elevate renal GSH fivefold. Previous studies in a renal artery occlusion model showed that pretreated kidneys in comparison to untreated controls were functionally impaired as measured by glomerular filtration rate, urine flow rate, and histology. To eliminate systemic effects of the pretreatment, kidneys were subjected to a fixed period of warm ischemia but flushed of blood and transplanted into nonpretreated syngeneic recipients. As before, pretreated kidneys exhibited marked functional impairment. We conclude that (i) elevation of renal GSH with GSH monoethyl ester enhances rather than prevents renal dysfunction and (ii) the enhancement of renal ischemic injury following pretreatment is not due to nonspecific systemic effects of GSH monoethyl ester pretreatment.
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PMID:The effect of glutathione content on renal function following warm ischemia. 265 99

Glutathione (GSH) is an important intracellular defense against reactive oxygen metabolites. Reaction of GSH with peroxides generates oxidized glutathione (GSSG). We hypothesized that reperfusion would cause oxidation of GSH and release of GSSG as a potential marker of intracellular oxidative reactions. Ten dogs underwent 90 min left anterior descending (LAD) occlusion and 30 min reperfusion. Coronary sinus (CS) plasma was sampled from the great cardiac vein, which drains the LAD region, and from the aorta at pre-ischemia (I), 90 min ischemia, and during reperfusion (R). We found that both GSSG and GSH increased in coronary sinus plasma during early reperfusion. (Formula: see text) Measured GSSG did not arise from autoxidation of plasma GSH. GSH and GSSG release from myocardium not only may be evidence of intracellular oxidative injury, but loss of GSH also could impair metabolism of peroxides during early reperfusion and predispose to further injury.
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PMID:Oxidation and release of glutathione from myocardium during early reperfusion. 275 94

The effects of several concentrations of amines and reducing agents on the activity of creatine (CK) and adenylate (AK) kinases were determined in homogenates of the brain of the rat at 0 and 37 degrees C. The order of decreasing irreversible inhibition of the enzymes was peroxide, 6-hydroxydopamine, dopamine, norepinephrine, 5-hydroxytryptamine. At 37 degrees C, approx. 50% of the activity of creatine kinase was lost in 30 min in the presence of 20 microM dopamine. 5-Hydroxytryptamine was several orders of magnitude less toxic. The action of dopamine was not prevented by inhibition of monoamine oxidase, chelation of metals or the addition of a catalase, indicating that formation of peroxide by monoamine oxidase was not the primary cause of the loss of enzyme. Although auto-oxidation of dopamine to a toxic quinone was considered, the degree of inhibition of creatine kinase was not affected when auto-oxidation was prevented under anaerobic conditions. Glutathione (GSH), present during the incubation, protected the enzymes but could not restore activity after exposure to amine. Concentrations of glutathione above 5 mM and of oxidized glutathione as low as 10 microM inhibited creatine kinase. Ascorbate protected the enzymes even when present at a concentration much less than that of the amine, but ascorbate was itself toxic. The findings indicate that dopamine, at concentrations attained after drug-induced release or ischemia, can be toxic to a metabolic enzyme present in the synaptosomal membrane.
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PMID:Amine-mediated toxicity. The effects of dopamine, norepinephrine, 5-hydroxytryptamine, 6-hydroxydopamine, ascorbate, glutathione and peroxide on the in vitro activities of creatine and adenylate kinases in the brain of the rat. 300 2

Oxygen-derived free radicals play an important role in the myocardial injury associated with ischemia and reperfusion. This study was designed to assess whether the protection afforded by a K+ rich, Mg2+ rich cardioplegic solution could be enhanced by the addition of free radical scavengers acting at different levels of the radical generating pathway. Forty isolated isovolumic rat hearts were divided into five groups (n = 8). Four groups of hearts were subjected to 90 minutes of normothermic cardioplegic arrest followed by 45 minutes of reperfusion. Hearts were given an initial bolus of either unmodified cardioplegic solution or cardioplegic solution enriched with superoxide dismutase (200,000 U/L) reduced glutathione (0.1 mmol/L), or peroxidase (6,000 U/L). One group of hearts was aerobically perfused throughout the experimental protocol and served as nonischemic controls. Based on comparisons of postreperfusion ventricular pressure development, maximal ventricular dP/dt, left ventricular compliance and coronary flow, peroxidase-containing cardioplegic solution afforded the best myocardial protection, with values of these indicators not significantly different from those of nonischemic perfused control heart. Glutathione afforded protection slightly inferior to that of peroxidase but still markedly better than in groups receiving superoxide dismutase or unmodified cardioplegic solution. This study confirms that cardioplegic protection can be enhanced by the addition of free radical scavengers, in particular peroxidase.
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PMID:A comparative study of free radical scavengers in cardioplegic solutions. Improved protection with peroxidase. 301 15

The relation between adenine nucleotide liver concentrations and the viability of liver allografts after cold preservation and warm ischemia was studied. A rat model was used with storage times defined in terms of allograft viability. Livers were excised and stored for 4 hr at 4 degrees C or 1 hr at 37 degrees C (viable if transplanted) or for 8 hr at 4 degrees C or 2 hr at 37 degrees C (not viable if transplanted) in a solution containing 0.9% NaCl and 2 mM CaCl2. Adenine nucleotide, malondialdehyde, and glutathione concentrations were measured in liver biopsies at the end of the storage periods and in control livers. During cold preservation, ATP concentrations decline, but degradation is largely halted at AMP, and this is independent of the length of storage or viability of the allograft. Graft failure is not due to lack of availability of intramitochondrial substrate (AMP) for rephosphorylation to adenosine triphosphate (ATP), nor is it likely that provision of such substrate will be helpful. On the other hand, with warm ischemia, degradation to inosine, hypoxanthine and xanthine occurs and nonviable livers develop higher levels of xanthine than viable ones; in fact, xanthine concentrations provide 100% discrimination between viable and nonviable warm preserved livers. Malondialdehyde concentrations were also significantly greater in the warm preserved nonviable livers, indicating that some lipid peroxidation may occur even before reperfusion of allografts. Glutathione concentrations were similar in all experimental groups.
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PMID:Adenine nucleotide tissue concentrations and liver allograft viability after cold preservation and warm ischemia. 328 45

Glutathione serves as an important intracellular defence against reactive oxygen metabolites and has been shown to be depleted from a number of tissues upon oxidative stress. In the present study we have investigated the levels of total glutathione (reduced + oxidized) in skeletal muscle of the rat after prolonged ischemia and reperfusion with and without treatment with hyperbaric oxygen (HBO) for the initial 45 minutes immediately following reperfusion. A tourniquet model for temporary, total ischemia was used, in which one hind leg was made ischemic for 3 or 4 hours. Muscle biopsies were taken after 5 hours of reperfusion. In postischemic muscle there was a significant decrease of total glutathione compared to control muscle, but in the 3-hour-ischemia-groups the loss of total glutathione was less in HBO treated animals than in untreated. HBO treatment also preserved ATP and PCr and decreased edema formation in the postischemic muscle following 3 hours of ischemia and reperfusion when compared to untreated animals. However, after 4 hours of ischemia, HBO treatment failed to improve any of these parameters in the postischemic muscle. Thus, our results demonstrate that HBO treatment lessens the metabolic, ischemic derangements and improves recovery in postischemic muscle after 3 hours of ischemia followed by reperfusion.
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PMID:Hyperbaric oxygen treatment attenuates glutathione depletion and improves metabolic restitution in postischemic skeletal muscle. 758 15

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