UMLS:C0022116 - FACTA Search

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Query: UMLS:C0022116 (ischemia)
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Our previous experimental studies showed that the liver is firstly and most severely involved in metabolic damage among various organs after hypoperfusion and sepsis. Changes of metabolites in liver and other organs as well as the function of circulating leukocytes were measured in three rat models with liver ischemia, or systemic hypoperfusion and sepsis. Partial liver ischemia 120 minutes after reperfusion not only resulted in significant decline of ATP and GSH levels in ischemic liver lobes but also in metabolic disorders in non-ischemic liver lobes, kidney, and small intestine. The amount of circulating white blood cells and zymosan stimulated chemoluminescence was increased. The findings showed that ischemic injury in partial liver may accelerate the whole liver damage and aggravate the metabolic disorders in other organs as well as the deterioration of homeostasis. Changes of liver sulfhydryl group levels and related metabolism were estimated. Significant decrease in liver sulfhydryl group levels during hypoperfusion and sepsis may contribute to various cellular metabolic disorders and destruction in early liver damage.
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PMID:[The liver in the pathogenesis of multiple organ failure]. 191 99

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

The pulmonary reimplantation response (PRR) is a form of membrane permeability pulmonary edema occurring in lung transplants. The severity of the PRR reflects the quality and duration of lung graft preservation. Free radicals formed during ischemia with reperfusion in the autotransplanted dog lung may play a role in producing PRR. We hypothesized that the addition of reduced glutathione (GSH) to the preservative solution could decrease PRR if hydroperoxides are being formed. Six dogs underwent left lung autotransplantation after the lung was flushed with Euro-Collins solution (EC). These dogs demonstrated radiographic and histopathologic evidence of bilateral pulmonary edema, greatest in the transplanted left lung. They also had increases in lung wet to dry weight (W/D) ratios in both lungs (left, 12.0 +/- 0.9; right, 10.1 +/- 0.8) as compared with a group of five unmanipulated control animals (left, 6.0 +/- 0.5; right, 7.0 +/- 0.4). Malondialdehyde (MDA) concentrations were significantly increased in the transplanted left lungs (14 +/- 4) from this group as compared with the controls (5 +/- 7). Five additional dogs underwent left lung autotransplantation with GSH added to the EC cryopreservation fluid. These animals did not develop histologic or radiographic evidence of pulmonary edema, and W/D ratios as well as MDA concentrations were not different from those in controls. To evaluate the effect of ischemia alone on changes in lung GSH concentrations, ten additional dogs underwent left pneumonectomy. Left lungs were cryopreserved in EC + GSH. In five of the animals, the right lung was removed and preserved in EC alone. In the other five animals, the right lung remained in vivo for 3 h and was then removed. Lung GSH concentrations were doubled after 3 h of ischemia when incubated in EC + GSH compared to in vivo controls and to EC-treated lungs. These data suggest that GSH added to the preservation fluid prevents PRR following transplantation and that lung GSH concentrations actually increase during preservation prior to reimplantation and reperfusion if the lung graft is exposed to GSH in the preservation fluid.
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PMID:Glutathione decreases the pulmonary reimplantation response in canine lung autotransplants. 195 16

The glutathione (GSH) content of rat kidney decreases after cessation of blood flow, falling to 40% of control levels 35 min after renal artery occlusion [R. C. Scaduto, Jr., V. H. Gattone II, L. W. Grotyohann, J. Wertz, and L. F. Martin. Am. J. Physiol. 255 (Renal Fluid Electrolyte Physiol. 24): F911-F921, 1988]. Renal GSH levels remained depressed for at least 2 h after resumption of blood flow. Because GSH functions in the removal of free radicals, and lipid peroxidation is a free radical-initiated process that occurs in the ischemic kidney, we investigated the fate of this GSH pool in the ischemic kidney. Using high-performance liquid chromatography to measure thiols, we found the loss of GSH to be associated with a stoichiometric accumulation of cysteine in the kidney. Moreover, preischemic labeling of the renal GSH pool with 35S led to accumulation of [35S]cysteine during ischemia that had the same specific activity as that of tissue GSH. Formation of cysteine during ischemia was suppressed in rats pretreated with acivicin, an inhibitor of gamma-glutamyltransferase (gamma-GT), although the degree of suppression was small in comparison to the extent of gamma-GT inhibition. During the initial 2 min of blood reflow after ischemia, tissue cysteine returned to control levels, and a transient increase in the cysteine content of renal venous blood was observed. After ischemia, renal GSH levels remained depressed, but postischemic GSH levels could be increased by administration of N-acetylcysteine during the ischemic period.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Glutathione catabolism by the ischemic rat kidney. 197 65

Myocardial sulfhydryl (SH)-containing compounds, including reduced glutathione (GSH), are both defenses against and potential markers of reactive oxygen metabolite injury during ischemia and reperfusion. We examined the alterations in GSH and other myocardial SH pools during reperfusion in anesthetized dogs exposed to brief (15 minutes, n = 7) or prolonged (90 minutes, n = 6) regional ischemia caused by occlusion of the left anterior descending artery. Ninety minutes of ischemia followed by 5 hours of reperfusion, which resulted in myocardial necrosis of 43.9 +/- 4.0% of the area at risk, caused a 22% reduction in total myocardial SH groups (p less than 0.01), a 57% decrease in nonprotein myocardial SH groups (p less than 0.01), a 56% decrease in GSH (p less than 0.01), and a 62% decrease in non-GSH, nonprotein SH groups (p less than 0.02). However, protein SH groups were not significantly reduced (12% decrease, p = NS). Also, myocardial release of GSH and oxidized glutathione (GSSG) into the coronary venous effluent occurred during early reperfusion. In contrast, 15 minutes of ischemia, followed by 30 minutes of reperfusion, did not alter myocardial total SH groups, protein SH groups, or GSH (9% decrease, p = NS); nor was there reperfusion release of GSH or GSSG. However, even with brief ischemia, nonprotein SH groups decreased 23% (p less than 0.05), due mainly to a 59% decrease in the non-GSH, nonprotein SH pool (p less than 0.05). These changes after brief ischemia occurred without alterations in myocardial GSSG or the GSH/GSSG ratio.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Myocardial sulfhydryl pool alterations occur during reperfusion after brief and prolonged myocardial ischemia in vivo. 199 59

The hypothesis that Kupffer cells and infiltrating neutrophils generate reactive oxygen in the hepatic sinusoids and may contribute to ischemia-reperfusion injury in the liver was investigated in a model of partial no-flow ischemia and reperfusion in male Fischer rats in vivo. During the reperfusion period of 60 min, plasma concentrations of glutathione disulfide (GSSG; index of oxidant stress) increased from 1.62 +/- 0.20 microM glutathione (GSH) equivalents to maximal values of 11.82 +/- 1.45 (45 min ischemia), 24.19 +/- 2.35 (60 min ischemia), and 70.20 +/- 7.8 (120 min ischemia). The basal tissue GSSG content in the postischemic lobes (0.19 +/- 0.02 nmol GSH eq/mg protein) increased by 50-100%. Although the number of neutrophils in liver and lung increased by 3- to 10-fold during reperfusion, there was no positive correlation between the number of neutrophils and the GSSG concentrations measured in plasma or tissue. However, activation of Kupffer cells with high doses of retinol or with Propionibacterium acnes significantly enhanced plasma GSSG levels, while inactivation of Kupffer cells with methyl palmitate or gadolinium chloride significantly attenuated the increase of plasma GSSG. Inactivation of Kupffer cells protected the liver significantly against ischemia-reperfusion injury. It is concluded that Kupffer cells are the predominant source of reactive oxygen formed during the initial reperfusion period and that Kupffer cell activity (including reactive oxygen formation) contributes to reperfusion injury in the liver in vivo.
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PMID:Neutrophil and Kupffer cell-induced oxidant stress and ischemia-reperfusion injury in rat liver. 200 3

Oxygen free radicals have been implicated as mediators of ischemia/reperfusion injury in a variety of organs. We investigated the role of oxidative injury and endogenous hepatic glutathione (GSH) in liver cell injury associated with complete hepatic ischemia and reperfusion. Forty-five minutes of complete hepatic ischemia followed by reperfusion caused an increase in serum GPT and a fall in hepatic GSH but no increase in hepatic lipid peroxidation products. Chemical depletion of hepatic GSH with diethyl maleate did not cause hepatocellular injury but augmented hepatic ischemia/reperfusion-induced SGPT release and promoted lipid peroxidation. Pretreatment with the selective, membrane-permeable oxygen radical scavenger dimethyl sulfoxide protected against the ischemia/reperfusion-induced drop in hepatic GSH but did not reduce SGPT release in normal rats. In rats sensitized to oxidative injury by depletion of endogenous GSH with diethyl maleate the oxygen radical scavenger protected against ischemia/reperfusion-induced lipid peroxidation and reduced the release of SGPT. These findings suggest that the rich hepatic supply with endogenous GSH has a crucial role in the protection against oxygen radical injury following short periods of total hepatic ischemia. Oxygen radical injury only occurs after depletion of these endogenous GSH stores.
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PMID:Oxygen free radicals and glutathione in hepatic ischemia/reperfusion injury. 202 Jan 91

Substantial evidence exists that reactive oxygen species participate in the pathogenesis of brain damage following both sustained and transient cerebral ischemia, adversely affecting the vascular endothelium and contributing to the formation of edema. One likely triggering event for free radical damage is delocalization of protein-bound iron. The binding capacity for some iron-binding proteins is highly pH sensitive and, consequently, the release of iron is enhanced by acidosis. In this study, we explored whether enhanced acidosis during ischemia triggers the production of reactive oxygen species. To that end, enhanced acidosis was produced by inducing ischemia in hyperglycemic rats, with normoglycemic ones serving as controls. Production of H2O2, estimated from the decrease in catalase activity after 3-amino-1,2,4-triazole (AT) administration, was measured in the cerebral cortex, caudoputamen, hippocampus, and substantia nigra (SN) after 15 min of ischemia followed by 5, 15, and 45 min of recovery, respectively (in substantia nigra after 45 min of recovery only). Free iron in cerebrospinal fluid (CSF) was measured after ischemia and 45 min of recovery. Levels of total glutathione (GSH + GSSH) in cortex and hippocampus, and levels of alpha-tocopherol in cortex, were also measured after 15 min of ischemia followed by 5, 15, and 45 min of recovery. The results confirm previous findings that brief ischemia in normoglycemic animals does not measurably increase H2O2 production in AT-injected animals. Ischemia under hyperglycemic conditions likewise failed to induce increased H2O2 production. No difference in free iron in CSF was observed between animals subjected to ischemia under hyper- and normoglycemic conditions. The moderate decrease in total glutathione or alpha-tocopherol levels did not differ between normo- and hyperglycemic animals in any brain region or at any recovery time. Thus, the results failed to give positive evidence for free radical damage following brief periods of ischemia complicated by excessive acidosis. However, it is possible that free radical production is localized to a small subcellular compartment within the tissue, thereby escaping detection. Also, the results do not exclude the possibility that free radicals are pathogenetically important after ischemia of longer duration.
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PMID:Acidosis-induced ischemic brain damage: are free radicals involved? 205 Jul 47

The objective of this study was to test the hypothesis that the extracellular oxidation of glutathione (GSH) may represent an important mechanism to limit hepatic ischemia/reperfusion injury in male Fischer rats in vivo. Basal plasma levels of glutathione disulfide (GSSG: 1.5 +/- 0.2 microM GSH-equivalents), glutathione (GSH: 6.2 +/- 0.4 microM) and alanine aminotransferase activities (ALT: 12 +/- 2 U/l) were significantly increased during the 1 h reperfusion period following 1 h of partial hepatic no-flow ischemia (GSSG: 19.7 +/- 2.2 microM; GSH 36.9 +/- 7.4 microM; ALT: 2260 +/- 355 U/l). Pretreatment with 1,3-bis-(2-chloroethyl)-1-nitrosourea (40 mg BCNU/kg), which inhibited glutathione reductase activity in the liver by 60%, did not affect any of these parameters. Biliary GSSG and GSH efflux rates were reduced and the GSSG-to-GSH ratio was not altered in controls and BCNU-treated rats at any time during ischemia and reperfusion. A 90% depletion of the hepatic glutathione content by phorone treatment (300 mg/kg) reduced the increase of plasma GSSG levels by 54%, totally suppressed the rise of plasma GSH concentrations and increased plasma ALT to 4290 +/- 755 U/l during reperfusion. The data suggest that hepatic glutathione serves to limit ischemia/reperfusion injury as a source of extracellular glutathione, not as a cofactor for the intracellular enzymatic detoxification of reactive oxygen species.
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PMID:Vascular oxidant stress and hepatic ischemia/reperfusion injury. 206 Aug 45

Functions of GSH in detoxication during radical-induced injury in specific pathological and toxicological conditions are discussed. GSH protects against oxidative damage in systems that scavenge radicals, eliminate lipid peroxidation products, preserve thiol-disulfide status of proteins, and repair oxidant damage. Several factors which affect cellular GSH homeostasis can affect these functions, including nutritional status, hypoxia and pharmacological intervention. Evidence from a variety of pathological and toxicological conditions, e.g. ischemia-reperfusion injury, chemically induced oxidative injury, radiation damage, aging, and degenerative diseases, indicate that GSH is a primary component of physiological systems to protect against oxidant and free-radical-mediated cell injury.
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PMID:Glutathione-dependent protection against oxidative injury. 219 57

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