Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0022116 (ischemia)
 91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hearts from rats treated with interleukin-1 (IL-1) intraperitoneally developed a rapid (6 h after IL-1), transient increase in neutrophils, tissue hydrogen peroxide (H2O2), and oxidized glutathione (GSSG) levels, and a subsequent (36 h after IL-1) increase in myocardial glucose-6-phosphate dehydrogenase (G6PD) activity and tolerance to ischemia-reperfusion. In the present investigation, we found that rats treated similarly with IL-1 had increased numbers of neutrophils in their kidneys, which were comparable to myocardial neutrophil increases, but did not develop increased renal tissue H2O2 or GSSG levels acutely (6 h after IL-1) or increased G6PD activity or resistance to ischemia-reperfusion injury later (36 h after IL-1). Our findings indicate that IL-1 treatment increased neutrophil accumulation in rat kidneys but did not increase oxidative stress, antioxidant enzyme activity, or resistance to ischemia-reperfusion injury. We conclude that organ-to-organ differences exist with respect to IL-1-induced tolerance.
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PMID:Interleukin-1 treatment increases neutrophils but not antioxidant enzyme activity or resistance to ischemia-reperfusion injury in rat kidneys. 784 98

Oxidized glutathione (GSSG) but not its reduced form (GSH) is taken up by intact myocardial cells, and is rapidly converted into GSH. Reduced glutathione is an important intracellular defense against oxygen-derived free radicals and has been found to enhance calcium sensitivity in skinned cardiac fibers. We have investigated the effects of intravenous GSSG on left ventricular systolic pressure, maximal rate of rise of pressure and regional segment-shortening in dogs subjected to occlusion of the left anterior descending artery for 30 minutes, followed by 45 minutes reperfusion. Starting 10 minutes before reperfusion, the dogs were randomly treated with either GSSG (100 mM, 5 ml/min, n = 5) or Ringer's solution (5 ml/min, n = 5) until 30 minutes of reperfusion. Myocardial blood flow was measured by radioactive microspheres. Infusion of GSSG increased total glutathione content in both ischemic (47 +/- 16 mumol/g protein) and nonischemic myocardium (71 +/- 17 mumol/g protein) as compared to controls (23 +/- 2 mumol/g protein, p < 0.05). In both groups paradoxical wall motion occurred in the ischemic region during occlusion. On reperfusion, regional dyskinesia persisted in controls; while, in glutathione-treated dogs, systolic segment-shortening reached half the baseline values (p < 0.05, treated vs controls, at 15, 30, 45 minutes reperfusion). During ischemia the area of pressure-length loops, obtained from simultaneous recordings of left ventricular pressure and regional segment length, decreased to 30 +/- 7% of baseline in controls and to 40 +/- 18% of baseline in GSSG-treated animals. After 45 minutes reperfusion it was restored to 78 +/- 22% baseline in treated hearts but was still 36 +/- 16 of baseline in controls (p < 0.05). We conclude that infusion of GSSG increases the intracellular stores of glutathione and improves the contractile state of postischemic myocardium.
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PMID:Infusion of oxidized glutathione enhances postischemic segment-shortening in dog hearts. 791 48

Changes in hepatic and biliary glutathione levels were studied in rat liver treated with tert-butyl hydroperoxide (t-BuOOH) and subjected to ischemia-reperfusion. Immediately after t-BuOOH administration, the oxidized glutathione (GSSG) values and reduced glutathione (GSSG/GSH) ratio in the bile increased dose-dependently and then returned to control level within 10 min, whereas the hepatic ATP level and bile flow rate were not affected by t-BuOOH at doses of up to 1.0 mmol/kg. These data suggested that the liver remains viable on treatment with up to 1.0 mmole/kg t-BuOOH, and that hepatocytes can rapidly dismute t-BuOOH at up to this dose. The hepatic GSH and GSSG levels did not vary appreciably during ischemia for 10 or 30 min or during subsequent reperfusion, but the GSSG/GSH ratio increased after ischemia for 30 min. The rate of bile flow and the biliary level of GSH decreased after ischemia for 30 min in proportion to the decrease in the hepatic ATP level. However, the biliary GSSG concentration did not vary on reperfusion, although GSSG secretion into the bile is also related to the hepatic ATP level. As a result, the GSSG/GSH ratio in the bile increased during reperfusion after ischemia for 30 min. This increased ratio is thought to reflect oxidation of hepatic GSH by hydroperoxide produced during reperfusion. The GSSG/GSH ratio in the bile after 30 min ischemia corresponded to that observed after a small dose (0.07 mmole/kg body wt) of t-BuOOH, which hepatocytes could dismute rapidly without loss of their viability.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Changes in biliary glutathione level during ischemia-reperfusion of rat liver. 796 94

The impact of cardiac hypertrophy on myocardial biochemical and physiological responses to ischaemia-reperfusion (I-R) was investigated in vivo. Hypertrophy was produced by aortic constriction (PH) or swimming training (TH). Open-chest rat hearts in PH, TH and a sedentary control group (SC) were subjected: (1) to ischaemia, by surgical occlusion of the main descending branch of the left coronary artery for 30 min; (2) to I-R, by releasing the occluded blood vessel for 15 min; or (3) to a sham operation. Ischaemia per se had little effect on heart oxidative and antioxidant status, or lipid peroxidation. However, I-R significantly decreased glutathione (GSH) content, increased glutathione disulfide (GSSG) content, and reduced GSH/GSSG ratio in the SC hearts. These alterations were associated with decreased activities of GSH peroxidase and GSSG reductase, and an increase in lipid peroxidation. Myocardial ATP, total adenine nucleotide content and energy charge in SC were significantly decreased after ischaemia, whereas levels of purine nucleotide derivatives, particularly adenosine, were elevated. No significant alteration of GSH status of adenine nucleotide metabolism occurred after ischaemia or I-R in hypertrophied hearts. In both PH and TH, glutathione content was significantly higher than in SC, whereas activities of GSH peroxidase and GSSG reductases were lower. TH rats maintained a higher heart rate (HR), peak systolic pressure, and energy charge during I-R. These data indicate that hypertrophied but well-functioned hearts may be more resistant to I-R induced disturbances of myocardial oxidative and antioxidant functions.
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PMID:Cardiac hypertrophy alters myocardial response to ischaemia and reperfusion in vivo. 797 1

Plasma levels of glutathione disulfide (GSSG) as an indicator of a vascular oxidant stress, tumor necrosis factor-alpha (TNF-alpha) formation, and liver injury (alanine aminotransferase activity, histology) were monitored in male Fischer rats after 30 min of hepatic ischemia followed by up to 4 hr of reperfusion. The injection of 1 mg/kg Salmonella enteritidis endotoxin at 30 min of reflow potentiated the postischemic oxidant stress and liver injury. TNF-alpha levels increased from 10 +/- 7 pg/ml (baseline) to 3,553 +/- 738 pg/ml after ischemia-reperfusion followed by endotoxin, or to 3,670 +/- 508 pg/ml after endotoxin alone. Depletion of serum complement before ischemia attenuated the endotoxin-mediated increase of reactive oxygen formation by 70% but did not affect TNF-alpha levels. Complement activation with cobra venom factor (CVF) during reperfusion had an effect similar to that of endotoxin on the oxidant stress and liver injury. CVF did not increase TNF-alpha formation during reperfusion. Kupffer cells and neutrophils isolated from the postischemic liver 2.5 hr after endotoxin injection generated 600% and 400% more superoxide, respectively, than cells isolated from control livers. The results demonstrate a substantial priming of hepatic phagocytes for reactive oxygen production but not TNF-alpha formation, even after short periods of hepatic ischemia, and the vulnerability of the postischemic liver to severe endotoxin-induced injury. Activated complement seems to be mainly responsible for the effects. These results may explain the high risk for hepatic failure after extensive liver resection and hypovolemic shock.
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PMID:Priming of phagocytes for reactive oxygen production during hepatic ischemia-reperfusion potentiates the susceptibility for endotoxin-induced liver injury. 798 73

The prevention of oxidant-induced damage following reperfusion was experimentally evaluated. Two pharmacological regimens containing different combinations of antioxidant factors and membrane-stabilizing compounds, such as alpha-tocopherol (vitamin E), methionine, dexamethasone, mannitol and cysteine, were administered. The reduced/oxidized glutathione (GSH/GSSG) ratio in muscle was used to evaluate oxidative stress. Ischaemia was induced by occluding the aorta and the inferior vena cava with an irrigation-occlusion catheter. After 4 h of ischaemia, five sheep were reperfused without any treatment (control group) and five treated with an endoaortic bolus administered at declamping (treatment 1). In five other sheep, treatment started during ischaemia (treatment 2). Ischaemia and, in particular, reperfusion significantly reduced the muscle GSH content, compared with the basal value in the control group; thus the GSH/GSSG ratio decreased significantly in the control group from 10.5(2.2) (mean(s.e.) basal value) to 0.687(0.3) at reperfusion (P < 0.009). Both treatments 1 and 2 significantly prevented a reduction in GSH content induced by reperfusion following ischaemia; the GSH/GSSG ratio (10.5(2.2) basal value) increased to 19.67(4.6) with reperfusion in the treatment group 1, mainly because of a lower decrease of GSH and a lower level of GSSG while it did not change in treatment group 2 (10.7(5.0)). Levels of creatine phosphokinase did not change in the treated groups, although they increased significantly in the control group (P < 0.006). Although oxidative stress is not the only cause of damage in revascularization, this study confirms the protective ability of treatment with free radical scavengers and membrane-stabilizing compounds.
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PMID:Prevention of reperfusion syndrome in acute muscular ischaemia with free radical scavengers and membrane-protecting compounds: an experimental study. 807 54

The GSH level in myocardial tissue represents an important defense mechanism against oxygen toxicity. Since the ischemia-induced depletion of GSH might favour the cytotoxicity of oxygen-derived free radicals produced during reperfusion, we assessed the effects of the GSH donor, glutathione monoethylester, in anaesthetized pigs subjected to 90 minutes of coronary occlusion followed by 30 minutes reperfusion. The drug was infused intracoronarily at a dose of 1 mg/ml (0.5 ml/min) throughout the experimental period. After coronary occlusion and reperfusion, we found a decrease in GSH, ADP, ATP and phosphocreatine levels in reperfused compared with non-ischemic tissue. Less evident were the differences in mitochondrial function, there being only a reduction in the reperfused tissue of the respiratory control index and state 3 respiration values when pyruvate was used as substrate. The infusion with glutathione monoethylester decreased the depletion of tissue GSH and improved the GSH/GSSG ratio, particularly in the non-ischemic tissue. Moreover, the drug decreased the mitochondrial dysfunction at the level of pyruvate utilization and partially prevented the fall in ATP in the reperfused tissue. This study confirms a possible protective effect of glutathione monoethylester in the prevention of reperfusion-induced myocardial damage.
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PMID:Effect of glutathione monoethyl ester on glutathione level and cardiac energetics in reperfused pig heart. 821 Jun 88

Parenchymal injury following reperfusion of the donor lung remains a significant problem in clinical lung transplantation. It has been postulated that free oxygen radicals act as local mediators of this event, and that tissue oxidized glutathione levels which reflect local free oxygen radical production, may be useful as an indicator of this regional ischemia-reperfusion injury. The glutathione redox cycle plays a physiologically important role in the endogenous antioxidant defense system. Intracellular glutathione depletion has been shown to render cells vulnerable to oxidant mediated injury. Adequate glutathione stores may be vital in protecting the cell from oxidant injury, especially the relatively exposed pulmonary epithelial cells. Single lung transplantation was carried out in 10 3- to 5-kg mongrel puppies, with a standard 2-hour ischemic time for the donor lung prior to reimplantation. Four hours following transplantation, lung tissue was harvested from both the transplanted and native lung of the recipient animal, and compared to normal lung tissue from the donor animal. Tissue was prepared for histological evaluation and glutathione assay. Tissue glutathione levels were determined via a spectrophotometric assay. For determination of oxidized glutathione (GSSG), samples were prepared with 2-vinylpyridine and N-ethylmaleimide (NEM) to derivatize all reduced glutathione and leave only GSSG for measurement by the fluorometric assay.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Reperfusion injury following single-lung transplantation: the tissue glutathione response. 826 91

We have examined the direct effects of oxidant metabolites on cardiac sarcolemmal phosphoinositide phospholipase C which transduces signals from various receptors for the modulation of intracellular Ca2+ levels. The enzyme activity in rat cardiac sarcolemmal membranes that had been preincubated (10 min; 37 degrees C) with xanthine-xanthine oxidase, a superoxide anion generating system, was not significantly affected. The addition to this system of superoxide dismutase, which converts superoxide anion to hydrogen peroxide (H2O2), resulted in a significant decrease of the enzyme activity in comparison with control values. Such decrease was fully prevented by catalase. Preincubation of sarcolemma with hypochlorous acid also gave a significant inhibition of phospholipase C, which was counteracted by the synthetic thiol reducer dithiothreitol. H2O2-pretreatment induced a concentration-dependent inhibition of the enzyme which was prevented by catalase but not by the iron chelator deferoxamine. Dithiothreitol was able to protect against, as well as to recover the enzyme activity from the H2O2 effects. These data suggest that superoxide anions and hydroxyl radicals did not interfere with phospholipase C activity, and that the nonradical oxidants, H2O2 and hypochlorous acid, may have acted through oxidation of thiol (SH) groups. The existence of reactive SH groups associated with the enzyme was confirmed by the inhibitory effects of SH modifiers (p-chloromercuriphenylsulfonic acid, 5'5'-dithio-bis(2-nitrobenzoic acid), N-ethylmaleimide and methyl methanethiosulfonate), which were prevented and in some cases also reversed by dithiothreitol. The biological reducer glutathione (GSH) was not able to recover the H2O2-induced inhibition of phospholipase C, whereas its oxidized form (GSSG) decreased the enzyme activity both in control and H2O2-pretreated membranes. The enzyme was active in a wide range of GSH/GSSG redox states, but H2O2 pretreatment narrowed this range. The results showed that oxidative stress changed the redox state of sarcolemmal phospholipase C, and this deactivated the enzyme. The oxidants' concentrations that significantly impaired phospholipase C in this study were compatible with those occurring in vivo during ischemia-reperfusion [Am. J. Med. 91(Suppl. 3C):235, 1991]. This supports the possibility that alteration of the receptor-associated phospholipase C may be a factor in the oxidant-related dysfunction of the ischemic-reperfused heart.
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PMID:Oxidative stress modifies the activity of cardiac sarcolemmal phospholipase C. 828 Jul 55

1. Surgical trauma has been associated with pre-anaesthesia fasting, anaesthetic toxicity, haemorrhage, hypovolaemic shock, and other pathological phenomena. Tissue glutathione (GSH), thiobarbituric acid-reacting substances (TBAR), and radical-trapping activity (RTA) have been determined at various time intervals after fasting, anaesthesia, and also after hepatic ischaemia and reperfusion as a model for haemorrhage and hypovolaemic shock. 2. Light ether anaesthesia of rats resulted in an immediate (5 min) and progressive decrease in liver and kidney total glutathione (GSH and GSSG), which was much greater in animals that had been fasted for 20 h. TBARs, a measure of lipid peroxidation, in rat liver and kidney increased as total GSH decreased. Fasting (20 h) alone decreased tissue GSH by 50%, and increased TBAR 100%; fasting plus 30 min of ether anaesthesia decreased tissue glutathione by 80 to 85%, and increased TBAR by some 600%. 3. Liver ischaemia alone decreased total liver GSH by 20% in the fed rat, and 50% in the fasted rat. Ischaemia, followed by reperfusion, decreased liver total GSH by 70% in the fed rat, and 90% in the fasted rat. The ratio of GSH/GSSG decreased from 16 in control animals to 7 in the fasted ischaemic rat, then to 1 in the fasted, ischaemic rat reperfused for 90 min. RTA of liver closely paralleled liver total GSH levels. TBAR was increased by ischaemia alone (50-100%), but more (400%) by 90 min reperfusion. 4. A complex series of molecular mechanisms including: (1) GSH depletion; (2) induction of CYP2E1 activity; (3) generation of reactive oxygen species; (4) lipid peroxidation; (5) cytokine release; and (6) leucocyte activation, are advanced to account for the toxic phenomena of surgical trauma and multiple system organ failure.
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PMID:Role of tissue glutathione in prevention of surgical trauma. 828 45


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