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)

With a variety of forms of ischemic and toxic tissue injury, cellular accumulation of Ca2+ and generation of oxygen free radicals may have adverse effects upon cellular and, in particular, mitochondrial membranes. Damage to mitochondria, resulting in impaired ATP synthesis and diminished activity of cellular energy-dependent processes, could contribute to cell death. In order to model, in vitro, conditions present post-ischemia or during toxin exposure, the interactions between Ca2+ and oxygen free radicals on isolated renal mitochondria were characterized. The oxygen free radicals were generated by hypoxanthine and xanthine oxidase to simulate in vitro one of the sources of oxygen free radicals in the early post-ischemic period in vivo. With site I substrates, pyruvate and malate, Ca2+ pretreatment, followed by exposure to oxygen free radicals, resulted in an inhibition of electron transport chain function and complete uncoupling of oxidative phosphorylation. These effects were partially mitigated by dibucaine, a phospholipase A2 inhibitor. With the site II substrate, succinate, the electron transport chain defect was not manifest and respiration remained partially coupled. The electron transport chain defect produced by Ca2+ and oxygen free radicals was localized to NADH CoQ reductase. Calcium and oxygen free radicals reduced mitochondrial ATPase activity by 55% and adenine nucleotide translocase activity by 65%. By contrast oxygen free radicals alone reduced ATPase activity by 32% and had no deleterious effects on translocase activity. Dibucaine partially prevented the Ca2+-dependent reduction in ATPase activity and totally prevented the Ca2+-dependent translocase damage observed in the presence of oxygen free radicals. These findings indicate that calcium potentiates oxygen free radical injury to mitochondria. The Ca2+-induced potentiation of oxygen free radical injury likely is due in part to activation of phospholipase A2. This detrimental interaction associated with Ca2+ uptake by mitochondria and exposure of the mitochondria to oxygen free radicals may explain the enhanced cellular injury observed during post-ischemic reperfusion.
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PMID:Mechanism of calcium potentiation of oxygen free radical injury to renal mitochondria. A model for post-ischemic and toxic mitochondrial damage. 287 85

Depletion of membrane phospholipids is known to be associated with myocardial ischemia, but its relationship to the injury involved with the reperfusion of ischemic myocardium is not known. The present study was designed to relate phospholipid degradation with reperfusion injury. The isolated in situ pig heart was subjected to 60 min of regional ischemia induced by occluding the left anterior descending (LAD) coronary artery and 60 min of global ischemia by hypothermic cardioplegic arrest followed by 60 min of reperfusion. The pigs were divided into two groups. In the treatment group, the heart was preperfused with mepacrine (0.05 mM), a known phospholipase inhibitor, for 15 min prior to LAD occlusion. In the control group, the total phospholipid content was not significantly decreased during LAD occlusion and arrest, but was reduced appreciably after reperfusion. Phosphatidylcholine, phosphatidylethanolamine, and phosphatidylinositol followed a similar pattern. The lowering of these phospholipids during reperfusion was accompanied by enhancement of lysophosphatidylcholine. Mepacrine restored the normal levels of these phospholipids. During reperfusion, fatty acyl CoA synthetase, lysophospholipase, and lysophosphatidylcholine acyltransferase were depressed, whereas phospholipase A2 was enhanced. Mepacrine inhibited phospholipase A2, but had no effects on the other enzymes. Mepacrine also provided significant protection against reperfusion injury, as documented by the preservation of high-energy phosphate compounds and inhibition of the appearance of creatine kinase activity in the perfusate. These results suggest that membrane phospholipids play an important role in myocardial injury associated with ischemia and reperfusion, primarily because the deacylation-reacylation cycle of phospholipid biosynthesis becomes defective.
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PMID:Role of membrane phospholipids in myocardial injury induced by ischemia and reperfusion. 294 42

Mitoplasts were prepared from 3-h ischemic livers in an attempt to define the structural alterations in the inner membrane that may account for the functional deficiencies of ischemic mitochondria. Mitoplasts from both control and ischemic livers had similar specific activities of cytochrome oxidase and succinate-cytochrome c reductase. With both preparations, the specific activity of rotenone-insensitive NADH-cytochrome c reductase was 10-fold lower than in the mitochondria from which they were prepared. Ischemic mitoplasts had no respiratory control with ADP, and had a slightly reduced phospholipid to protein ratio and an increased cholesterol to protein ratio. As a result, the cholesterol to phospholipid molar ratio was increased from the control of 0.04 to 0.08. There were also differences in the content of individual phospholipid species. Phosphatidylcholine increased by 15%, while cardiolipin decreased by 60%. There were increases in sphingomyelin and in the lysophospholipids of phosphatidylcholine, ethanolamine, and cardiolipin. Pretreatment with chlorpromazine did not prevent these changes. Linoleic acid was decreased by 35% in ischemic phospholipids, and the content of free fatty acids was increased 4-fold. Electron spin resonance spectroscopy of mitoplasts spin labeled with either 5- or 12-doxyl stearic acid revealed an increased molecular order (decreased fluidity) of ischemic inner mitochondrial membranes consistent with the increased cholesterol to phospholipid ratio. The data indicate activation of a phospholipase A in ischemic mitochondria with the resulting accumulation of products of lipid hydrolysis. This conclusion further emphasizes the close similarity between the structural and functional consequences of ischemia in the intact animal and the effect on isolated mitochondria of the activation of the endogenous phospholipase A. In both cases the major functional alterations are attributable to changes in the permeability of the inner mitochondrial membrane induced by the accumulation of lysophospholipids.
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PMID:Structural alterations of the inner mitochondrial membrane in ischemic liver cell injury. 298 20

This study addresses the question of whether the cyclooxygenase inhibitors indomethacin and diclofenac and the glucocorticosteroid dexamethasone ameliorate neuronal necrosis following cerebral ischemia. In addition, since these drugs inhibit the production of prostaglandins and depress phospholipase A2 activity, respectively, the importance of free fatty acids (FFAs) on the development of ischemic neuronal damage was assessed. Neuronal damage was determined in the rat brain at 1 week following 10 min of forebrain ischemia. The cyclooxygenase inhibitors, whether given before or after ischemia, failed to alter the brain damage incurred. Animals given dexamethasone were divided into three groups and the drug was administered at a constant dosage of 2 mg/kg: (a) 2 days, 1 day, and 3 h intraperitoneally before (chronic pretreatment), (b) 3 h intraperitoneally before (acute pretreatment), and (c) 5 min intravenously and 6 h and 1 day intraperitoneally after (chronic posttreatment) induction of ischemia. Acute pretreatment did not affect the histopathological outcome. Chronic posttreatment of animals with dexamethasone ameliorated the damage inflicted on the caudate nucleus, but had no effect on other brain areas investigated. Unexpectedly, the chronic pretreatment aggravated the brain damage and caused seizures following ischemia. Histopathological data showed massive neuronal damage in these brains. The accumulation of FFA levels during ischemia was markedly suppressed, and the decrease in the energy charge was curtailed by chronic pretreatment with dexamethasone. However, brain glucose levels in control animals and lactic acid concentrations following 10 min of ischemia were significantly higher both in the cerebral cortex and in the hippocampus of dexamethasone-treated animals. These results suggest that aggravation of neuronal necrosis by chronic dexamethasone pretreatment could be ascribed to lactic acidosis due to hyperglycemia in combination with an action of dexamethasone on glucocorticoid receptors in the brain.
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PMID:Chronic dexamethasone pretreatment aggravates ischemic neuronal necrosis. 309 61

Phospholipids are believed to play an important role in pathology and physiology of the myocardium. Because of the distinct physico-chemical properties of plasmalogens we studied the plasmalogen content and distribution in the sarcolemma of cultured rat myocytes. Treatment with phospholipase A2 degraded all glycerophospholipids in the outer monolayer. The hydrolysis products were analyzed for plasmalogen content. It is shown that the inner sarcolemmal leaflet is highly enriched in phosphatidylcholine and ethanolamine plasmalogen. This distribution of the plasmalogens might affect bilayer stability and thereby be involved in the destruction of the sarcolemma upon ischemia and reperfusion.
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PMID:Plasmalogen content and distribution in the sarcolemma of cultured neonatal rat myocytes. 319 2

Phospholipid catabolism is thought to be one of the critical events in membrane injury during heart ischemia. In this work, the enzymes involved in phospholipid metabolism were studied in purified cultured ventricular myocytes in normoxic and hypoxic conditions. Purified ventricular myocytes exhibited an alkaline phospholipase A activity which had sn-2 specificity and which was calcium dependent, and an acid phospholipase A activity with sn-1 specificity. These cells also exhibited lysophospholipase and acyl-CoA/lysophosphatidylcholine acyltransferase activities. Oxygen deprivation of the myocardial cells for 4 h resulted in a sharp reduction of both phospholipase A2 and A1 activities. The activities of the other lipolytic enzymes were unaffected by hypoxia. Although hypoxia resulted in a marked increase of lactate dehydrogenase leakage in the bathing fluid, no additional release of the lipolytic enzymes and mitochondrial enzyme was observed. However, we noted an important alkaline phospholipase A2 leakage during normoxia. It is suggested that ventricular myocytes, under hypoxia, tend to prevent phospholipid degradation by reducing their phospholipase A activities.
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PMID:Activities of some enzymes of phospholipid metabolism in cultured rat ventricular myocytes in normoxic and hypoxic conditions. 333 66

Vasodepressor prostanoids have been suggested to regulate renal hemodynamics after nephrotoxic injury and thus protect the kidney against the effects of prolonged ischemia. This study assessed whether changes in two microvascular vasodilator prostanoids would correlate with changes seen in renal hemodynamics in rabbits with nephrotoxic renal injury produced by either uranyl nitrate or mercuric chloride. Rabbits were killed at 3, 24, and 72 h after the nephrotoxin injections and 6-ketoprostaglandin (PG) F1 alpha and PGE2 synthesis was measured in vitro in isolated renal microvessels. At the end of 24 h, synthesis of both prostanoids was significantly increased in all nephrotoxin-treated animals, an observation not noted at the end of 3 h. At 72 h, 6-keto-PGF1 alpha production remained elevated. Pretreatment with mepacrine blocked the increased prostanoid production seen in uranyl nitrate-treated animals. Thus, renal microvascular vasodilator prostanoid biosynthesis is increased 24-72 h after nephrotoxin administration. These data suggest that the biosynthesis of prostacyclin and PGE2 may contribute to the maintenance of renal blood flow in the first few days after acute renal injury and further suggest that a mechanism for this increase may be stimulation of phospholipase A2.
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PMID:Alterations in rabbit renal microvascular prostanoid synthesis in acute renal failure. 336 78

Amiodarone is used extensively for the chronic treatment of life-threatening arrhythmias caused by ischemic heart disease. However, chronic therapy with this agent results in phospholipidosis in various tissues and it has been suggested that the inhibition of lysosomal phospholipase A by this drug contributes to this abnormality. Exogenous amiodarone has been shown to inhibit purified rat liver lysosomal phospholipase A1, as well as acid phospholipase activities of alveolar macrophage homogenates and those of snake venom phospholipase A2 and bacterial phospholipase C. The effects of drug treatment on heart have not been explored. The results described here demonstrate that amiodarone also significantly increases (37%, p less than 0.001) phospholipid content in cat hearts. This increase is proportionately distributed to all major phospholipid classes, with the exception of sphingomyelin which appears to increase more than the others. In addition, the data also show that following amiodarone treatment, the endogenous drug levels in the heart were sufficient to reduce in vitro losses of membrane phospholipid at 37 degrees C by inhibiting a variety of endogenous phospholipases at physiological (7.4), ischemic (6.2) and acidic (5.0) pH values. This protection is more pronounced at acidic pH values than at physiological pH. Endogenous amiodarone also affects myocardial phospholipase activities towards exogenous phosphatidylcholine and again the extent of inhibition is more at acidic pH. These results suggest that amiodarone induces phospholipidosis in the heart by inhibiting phospholipid catabolism and that its antiarrhythmic properties may reside in its ability to modulate alkaline, neutral and acid phospholipase activities in ischemia. To what extent amiodarone metabolites (desethylamiodarone and bis-desethylamiodarone) are involved in these actions remains to be determined.
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PMID:Effects of chronic amiodarone treatment on cat myocardial phospholipid content and on in vitro phospholipid catabolism. 345 65

Pretreatment of the ischemic myocardium with verapamil protects against mitochondrial respiratory depression observed during ischemic arrest as well as during reperfusion. Since ischemic mitochondrial function appears not to be altered further by reperfusion, the purpose of this study is to identify a biochemical event affecting mitochondria that is specifically associated with reperfusion injury. It has been proposed that increased cellular Ca2+ influx and oxygen toxicity may result from reintroduction of coronary flow. Increased cytosolic Ca2+ is transmitted to the mitochondria with subsequent activation of Ca2+-dependent events, including phospholipase A2. Net production of lysophospholipids (and loss of total diacylphospholipids from the mitochondria) will proceed when reacylation mechanisms are inhibited. Since acyl-CoA:lysophospholipid acyltransferase is a sulfhydryl-sensitive enzyme and since increased activity of glutathione peroxidase shifts the levels of the mitochondrial sulfhydryl buffer, glutathione, towards oxidation, levels of glutathione and its oxidation state were measured during reperfusion in the absence or presence of verapamil pretreatment. Ischemia lowers total glutathione and reduces the redox ratio (reduced glutathione: oxidized glutathione) by 85%. Reperfusion partially returns the redox ratio to control by causing oxidized glutathione to disappear from the matrix. Verapamil maintains both the concentration and the redox potential of glutathione at control levels. Concomitant with alterations in reduced glutathione:oxidized glutathione is a decrease in ischemic mitochondrial phospholipid content. During reperfusion, phosphatidylethanolamine and its major constituent fatty acids (C 18:0 and C 20:4) are specifically lost from the mitochondrial membrane. Accompanying the significant loss of arachidonic acid during reperfusion is the decreased content of 11-OH, 12-OH, and 15-OH arachidonate. These lipid peroxidation products are not increased in ischemia. It is proposed that oxidation of matrix glutathione to glutathione disulfide during ischemia results in formation of glutathione-protein mixed disulfides and inhibition of sulfhydryl-sensitive proteins, including acyl-CoA lysophosphatide acyltransferase. Thus, metabolic events occurring within the ischemic period set the stage for prolonged dysfunction during reperfusion.
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PMID:Protection by verapamil of mitochondrial glutathione equilibrium and phospholipid changes during reperfusion of ischemic canine myocardium. 362 93

Oxygen free radicals and phospholipid degradation have been implicated in the pathogenesis of ischemia and reperfusion injury. The present study examines the involvement of such mechanisms in myocardial reperfusion injury in neonatal hearts. The isolated neonatal pig hearts from two different age groups, 0 to 2 days old (newborn) and 7 to 9 days old (week-old), were subjected to 60 min of normothermic global ischemia followed by 60 min of reperfusion. Although myocardial ischemia reduced superoxide dismutase, catalase, and glutathione peroxidase activities in both age groups, superoxide dismutase and catalase activities remained significantly lower in the newborn pig heart during ischemia and reperfusion. Oxidized glutathione release from the neonatal pig hearts was at minimum levels before ischemia, but it increased 10-fold at the onset of reperfusion and was significantly higher in the newborn heart. This indicates that generation of oxygen free radicals was enhanced in the newborn compared with that in the week-old heart. The increase in phospholipase A2 activity and decrease in acyl CoA synthetase and lysophosphatidylcholine acyl transferase activities during ischemia and reperfusion were associated with comparable loss of membrane phospholipids and accumulation of lysophosphatidylcholine and free fatty acids in both age groups, except that oleic acid content was significantly higher in the newborn heart during reperfusion. Myocardial damage appears to be potentiated in the newborn heart during reperfusion, as evidenced by higher release of creatine kinase and a lower content of high-energy phosphates. These results indicate that oxygen free radicals may play a crucial role in the occurrence of reperfusion injury in immature hearts.
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PMID:The mechanism of myocardial reperfusion injury in neonates. 366 15

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