Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.11.1.6 (catalase)
 55,569 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Excessive stimulation of excitatory amino acid (EAA) receptors and abnormal production of oxygen-derived free radicals have repeatedly been implicated in the series of events linking brain hypoxia or ischemia to neuronal death. We report here that in rat hippocampal slices the KCl-stimulated output of labeled D-3H aspartate or of endogenous aspartate and glutamate significantly increased under in vitro simulated hypoxic, hypoglycemic, or ischemic conditions. In particular, when the slices were incubated for 10 min at 32 degrees C under "ischemic" conditions (namely, lack of oxygen and glucose), endogenous aspartate and glutamate in the supernatant increased by 10 and 20 times, respectively. Since radical scavengers (D-mannitol), drugs reducing free radical formation (indomethacin, corticosteroid), or enzymes able to metabolize them (catalase and superoxide dismutase) significantly reduced this output, it was supposed that free radicals caused EAA release. A direct demonstration of this concept was obtained by showing a significant release of EAA after incubation of hippocampal slices with enzymes and substrates known to cause the formation of free radicals, such as xanthine plus xanthine oxidase or arachidonic acid plus prostaglandin synthase. Neither ischemia nor the enzymatic reactions leading to free radical production increased the activity of the cytoplasmic enzyme lactate dehydrogenase in the incubation medium, thus ruling out a nonspecific cellular lysis. It appears therefore that during ischemic states, brain production of reactive molecules (free radicals) causes an increased output of EAA. This may trigger a series of events which could help to explain the delayed loss of neurons after a transient ischemic period.
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PMID:Excitatory amino acid release and free radical formation may cooperate in the genesis of ischemia-induced neuronal damage. 196 65

Thirteen immature puppies (2 to 4 kg) underwent 1 hour of acute hypoxia (oxygen tension 25 to 30 mm Hg), followed by 45 minutes of normothermic global ischemia on total vented bypass with normal blood reperfusion. Ventricular function was assessed by inscribing Starling function curves and measuring stroke work indices before hypoxia and after reperfusion. Seven puppies (control) received normal saline infusion at 4 ml/kg/hr. Six other puppies received a 4 ml/kg/hr intravenous infusion of glutamate/aspartate, glucose-insulin-potassium, mercaptopropionyl glycine, carnitine, and catalase during hypoxia and reperfusion. In control hearts, acute hypoxia depleted myocardial glutamate and aspartate by 52% (p less than 0.05 versus prehypoxia) and 48% (p less than 0.05 versus prehypoxia) and caused severe hemodynamic deterioration (55% decrease of stroke work index) (p less than 0.05 versus prehypoxia); three of seven (43%) required premature institution of bypass. Postischemic left ventricular function recovered to only 40% of control levels (p less than 0.05 versus prehypoxia). In contrast, intravenous metabolic infusions maintained tissue glutamate (p less than 0.05 versus control group) and aspartate (p less than 0.05 versus control group) in treated hearts during hypoxia and allowed cardiac index to rise 20% (p less than 0.05 versus prehypoxia); all treated hearts tolerated 1 hour of hypoxia, and stroke work recovered 70% (p less than 0.05 versus control group) of stroke work index after subsequent ischemia. Impaired tolerance of immature hearts to acute hypoxia and subsequent ischemia is due to substrate depletion. This impairment can be reduced by intravenous metabolic support during hypoxia and reperfusion and leads to improved recovery of postischemic function.
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PMID:Studies of myocardial protection in the immature heart. IV. Improved tolerance of immature myocardium to hypoxia and ischemia by intravenous metabolic support. 149 25

We have applied the Luminol enhanced chemiluminescence technique to the isolated perfused rat liver during ischemia and reperfusion to monitor the production of oxygen radicals in tissue. Livers under perfusion with Luminol-containing buffer were subjected to 30 minutes of global ischemia followed by 60 minutes of reperfusion. Their chemiluminescence was continuously monitored to obtain the time course of oxygen radical production. Transient bursts of oxygen radical production were observed in the livers as indicated by chemiluminescence changes on reperfusion. Superoxide dismutase treatment abolished while catalase treatment enhanced the reperfusion-induced chemiluminescence transient.
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PMID:Oxygen radical production during ischemia-reperfusion in the isolated perfused rat liver as monitored by luminol enhanced chemiluminescence. 198 1

The objective of this study was to determine the effect of oxygen and the oxygen radical-scavenging enzyme catalase on the neonatal rabbit heart exposed to global ischemia. The experiments were performed with an isolated neonatal (7 to 10 days of age) working heart model in which normothermic (37 degrees C) ischemia was produced for 60 minutes. Left ventricular developed pressure, ratio of change of ventricular pressure to change in time, and aortic flow were measured before ischemia and 30 minutes after reperfusing the hearts with physiologic saline solution. In the control group (ischemia only), developed pressure and ratio of change of ventricular pressure to change in time recovered to 27% +/- 3% (mean +/- standard error of the mean) and 24% +/- 7% of baseline; the hearts were incapable of ejecting (aortic flow = 0). Treatment of hearts before and after ischemia with catalase (150 units/ml of perfusate) was studied in a second group (control plus catalase), but functional recovery (developed pressure = 32% +/- 1%; ratio of change of ventricular pressure to change in time = 24% +/- 2%, and aortic flow = 0) was not significantly different from the control group. The effect of washout midway through the ischemic period with a low oxygen (oxygen concentration less than 35 mm Hg) solution was measured in a third group (hypoxic physiologic saline solution). Functional recovery (developed pressure = 13% +/- 3%; ratio of change of ventricular su pressure to change in time = 13% + 2%; aortic flow = 0) was not significantly different from the control and control plus catalase groups. In marked contrast were the effects of washout with an oxygenated (oxygen concentration greater than 500 mm Hg) solution (oxygenated physiologic saline solution) in which functional recovery (developed pressure = 78% +/- 3%; ratio of change of ventricular pressure to change in time = 80% +/- 3%; aortic flow = 39% +/- 9%) was significantly better than in the control, control plus catalase, and hypoxic physiologic saline solution groups. Use of modified St. Thomas' Hospital cardioplegic solution (cardioplegic solution group) during the ischemic period also resulted in substantial functional recovery (developed pressure = 80% +/- 3%; ratio of change of ventricular pressure to change in time = 78% +/- 5%; aortic flow = 64% +/- 7%) that did not differ significantly from that in the oxygenated physiologic saline solution group.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Recovery of the neonatal heart after normothermic ischemia. Effect of oxygen and catalase. 199 43

Trolox, a hydrophilic analog of vitamin E, was reported to scavenge peroxyl radicals from artificial systems better than its parent compound. Here we examined the possible cytoprotective effect of Trolox in cultured hepatocytes and in the rat liver. In cultured rat hepatocytes, 0.5 to 16 mmol/L Trolox (with optimum between 1 to 2 mmol/L) was observed to prolong the survival of cells exposed to oxyradicals generated with xanthine oxidase-hypoxanthine. The protection by 1 mmol/L Trolox surpassed that provided by either ascorbate, mannitol, superoxide dismutase and/or catalase--each at a level giving its maximal protection in the same system. In both a global and partial model of hepatic ischemia-reperfusion in rats, infusion of Trolox (7.5 to 10 mumol/kg body weight) just before reflow reduced by greater than 80% the liver necrosis sustained in untreated (no Trolox) control rats. Such organ salvage was apparently accompanied by approximately 50% reduction in the amount of hepatic conjugated dienes, which were quantified by a highly specific radiochemical assay. Since conjugated dienes are presumed to be good "markers" of oxyradical damage, our data may have provided a semiquantitative link between free radical-induced necrosis and its chemical imprint in vivo. The data also indicated a relatively rapid and potent antioxidant-like action by Trolox on rat hepatocytes and on the postischemic reperfused rat liver.
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PMID:Trolox protects rat hepatocytes against oxyradical damage and the ischemic rat liver from reperfusion injury. 199 27

Cytotoxicity resulting from the interaction of fluorescent light from a flow hood with Hepes-buffered cell culture medium at room temperature was demonstrated. Toxicity was prevented by keeping both cells (V79 Chinese hamster) and medium shielded from direct fluorescent light ("dark conditions") or by supplementing the medium with 10 micrograms/ml catalase; this suggests that extracellular hydrogen peroxide is a major cause of the lethal effect under "lighted conditions." No sensitization resulted from the exposure of cells in a sodium bicarbonate (SBC)-buffered medium to fluorescent light, nor in a catalase supplemented SBC-buffered medium. The Hepes/light reaction during routine cell manipulations presensitized cells to hypothermia damage in the dark with the presensitization being more severe for 5 than for 10 degrees C hypothermic exposure. Presensitization was prevented by performing the complete experiment under dark conditions or by supplementing the medium with 10 micrograms/ml catalase. However, catalase did not improve the hypothermic survival when experiments were performed under dark conditions. Hence, 10 micrograms/ml catalase does not protect cells from hypothermic (5 and 10 degrees C) damage per se, but rather from Hepes/light sublethal damage which interacts with hypothermic sublethal damage to result in lethal lesions. Additionally, under dark conditions, superoxide dismutase (SOD), allopurinol, catalase plus SOD, DMSO, or mannitol did not improve survival when present during hypothermic storage, suggesting that extracellular superoxide anion, hydrogen peroxide, or hydroxyl radicals are not the cause of cell killing under conditions of pure hypothermia uncomplicated by prehypothermic ischemia or hypoxia.
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PMID:Factors influencing survival of mammalian cells exposed to hypothermia. V. Effects of hepes, free radicals, and H2O2 under light and dark conditions. 201 62

Free radicals may arise from a number of sources as a result of a variety of cellular mechanisms; they are generated under both normal and pathological circumstances. The xanthine oxidase pathway, the arachidonic acid pathway, invading leucocytes, catecholamine oxidation, and mitochondrial activity can all lead to the production of a variety of reactive oxygen intermediates including superoxide, hydrogen peroxide, and the hydroxyl radical. Whatever their source, free radicals can be extremely toxic to the cell and they are capable of causing major membrane injury by initiating lipid peroxidation or by altering the activity of membrane-bound enzyme systems which control ionic movement. The cell possesses highly efficient protective mechanisms, including antioxidants such as vitamins C and E and the enzymes superoxide dismutase and catalase, all of which are designed to prevent the occurrence of free radical-induced injury under normal conditions. However, during ischaemia and reperfusion, these protective mechanisms may be overwhelmed and severe free radical-mediated injury may occur. Ischaemia may prime the myocardium for free radical-induced injury. The great majority of the evidence that manipulation of free radicals may protect against such injury is, however, circumstantial.
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PMID:Free radicals and the heart. 202 51

Washed human platelets prevent edema formation in isolated rabbit lungs infused with xanthine oxidase, an enzyme that injures endothelial membranes by generating extracellular oxidants. We hypothesized that platelets would similarly preserve membrane permeability in isolated lungs exposed to ischemia-reperfusion injury, a model that perturbs endothelial cells by the generation of intracellular oxidants. Isolated perfused rabbit lungs (IPL) were exposed to warm ischemia-reperfusion to cause lung edema. The infusion of washed human platelets (1.05 +/- 0.02 x 10(10) cells) prevented edema formation as measured by lung weight gain, wet-to-dry lung weight ratios, histological edema, and preservation of paraendothelial cell tight junctions. Inhibition of the platelet glutathione redox cycle with 1,3-bis(2-chloroethyl)-1-nitrosourea, dehydroepiandrosterone, or 1-chloro-2,4-dinitrobenzene interfered with platelet protective effects. In contrast, inhibition of platelet catalase with aminotriazole and H2O2 had no effect on platelet protection. Lung tissue malonyldialdehyde concentrations were similar in isolated lungs exposed to ischemia-reperfusion with or without the infusion of platelets. These results indicate that platelet attenuation of ischemia-reperfusion lung edema depends on platelet glutathione redox cycle antioxidants but not platelet catalase.
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PMID:Washed human platelets prevent ischemia-reperfusion edema in isolated rabbit lungs. 203 73

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

It is now becoming increasingly clear that free radicals contribute to brain damage in several conditions, such as hyperoxia and trauma. It has been more difficult to prove that free radical production mediates ischemic brain damage, but it has often been suggested that it may be a major contributor to reperfusion damage, observed following transient ischemia. Recent results demonstrate that cerebral ischemia of long duration, particularly when followed by reperfusion, leads to enhanced production of partially reduced oxygen species, notably hydrogen peroxide (H2O2). It has also been suggested that postischemic hyperoxia, e.g. an increased oxygen tension during the recirculation period, adversely affects recovery following transient ischemia. Other data support the notion that brain damage caused by permanent ischemia (stroke) is significantly influenced by production of free radicals. The present study, however, fails to show that recirculation following brief periods of ischemia (15 min) leads to an enhanced H2O2 production, and that hyperoxia aggravates the ischemic damage. This study was undertaken to reveal whether variations in oxygen supply in the postischemic period following forebrain ischemia in rats affect free radical production and the brain damage incurred. To that end, rats ventilated on N2O/O2 (70:30) were subjected to 15 min of transient ischemia. Normoxic animals were ventilated with the N2O/O2 mixture, hyperoxic animals with 100% O2, and hypoxic ones with about 10% O2 (balance either N2O/N2 or N2) during the recirculation. At the end of this period, the animals were decapitated for assessment of H2O2 production with the aminotriazole/catalase method. This method is based on the notion that aminotriazole interacts with H2O2 to inactivate catalase; thus, the rate of inactivation of catalase in aminotriazole treated animals reflects H2O2 production. In a parallel series, animals ventilated with one of the three gas mixtures in the early recirculation period, respectively, were allowed to recover for 7 days, with subsequent perfusion-fixation of brain tissues and light microscopical evaluation of the brain damage. Animals given aminotriazole, whether rendered ischemic or not, showed a reduced tissue catalase activity, reflecting H2O2 production in the brain. Hyperoxic animals failed to show increased tissue H2O2 production, while hypoxic ones showed a tendency towards decreased production. However, all three groups (hypo, normo- and hyperoxic) had similar density and distribution of neuronal damage. These results suggest that although postischemic oxygen tensions may determine the rates of H2O2 production, variations in oxygen tensions do not influence the final brain damage incurred.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Free radical production and ischemic brain damage: influence of postischemic oxygen tension. 205 15


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