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

The present study was undertaken to examine whether dichloroacetate, which inhibits pyruvate dehydrogenase kinase and, therefore, increases the activity of pyruvate dehydrogenase, attenuates myocardial acidosis and metabolic changes induced by coronary occlusion. In dogs anesthetized with pentobarbital, the left anterior descending coronary artery was incompletely occluded to reduce the left anterior descending flow to a half to one third of the original flow (partial occlusion) to produce myocardial (regional) ischemia. Partial occlusion was continued for 90 min, and a bolus injection of saline or dichloroacetate was made intravenously 30 min after the onset of occlusion. Partial occlusion decreased myocardial pH significantly. An injection of dichloroacetate (150 mg/kg) increased myocardial pH that had been lowered by partial occlusion. Myocardial metabolites were measured in other dogs. Partial occlusion decreased the myocardial levels of adenosine triphosphate, creatine phosphate and energy charge potential, and increased that of lactate significantly, without affecting the myocardial levels of pyruvate and nonesterified fatty acids. Dichloroacetate attenuated the ischemia-induced changes in the myocardial levels of adenosine triphosphate, creatine phosphate, energy charge potential and lactate. These results indicate that dichloroacetate attenuates the myocardial acidosis and metabolic changes during coronary partial occlusion.
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PMID:Dichloroacetate attenuates myocardial acidosis and metabolic changes induced by partial occlusion of the coronary artery in dogs. 209 18

The quantitative importance of glycolysis in cardiomyocyte reenergization and contractile recovery was examined in postischemic, preload-controlled, isolated working guinea pig hearts. A 25-min global but low-flow ischemia with concurrent norepinephrine infusion to exhaust cellular glycogen stores was followed by a 15-min reperfusion. With 5 mM pyruvate as sole reperfusion substrate, severe contractile failure developed despite normal sarcolemmal pyruvate transport rate and high intracellular pyruvate concentrations near 2 mM. Reperfusion dysfunction was characterized by a low cytosolic phosphorylation potential [( ATP]/[( ADP][Pi]) due to accumulations of inorganic phosphate (Pi) and lactate. In contrast, with 5 mM glucose plus pyruvate as substrates, but not with glucose as sole substrate, reperfusion phosphorylation potential and function recovered to near normal. During the critical ischemia-reperfusion transition at 30 s reperfusion the cytosolic creatine kinase appeared displaced from equilibrium, regardless of the substrate supply. When under these conditions glucose and pyruvate were coinfused, glycolytic flux was near maximum, the glyceraldehyde-3-phosphate dehydrogenase/3-phosphoglycerate kinase reaction was enhanced, accumulation of Pi was attenuated, ATP content was slightly increased, and adenosine release was low. Thus, glucose prevented deterioration of the phosphorylation potential to levels incompatible with reperfusion recovery. Immediate energetic support due to maximum glycolytic ATP production and enhancement of the glyceraldehyde-3-phosphate dehydrogenase/3-phosphoglycerate kinase reaction appeared to act in concert to prevent detrimental collapse of [ATP]/[( ADP][Pi]) during creatine kinase dysfunction in the ischemia-reperfusion transition. Dichloroacetate (2 mM) plus glucose stimulated glycolysis but failed fully to reenergize the reperfused heart; conversely, 10 mM 2-deoxyglucose plus pyruvate inhibited glycolysis and produced virtually instantaneous de-energization during reperfusion. The following conclusions were reached. (1) A functional glycolysis is required to prevent energetic and contractile collapse of the low-flow ischemic or reperfused heart (2). Glucose stabilization of energetics in pyruvate-perfused hearts is due in part to intensification of glyceraldehyde-3-phosphate dehydrogenase/3-phosphoglycerate kinase activity. (3) 2-Deoxyglucose depletes the glyceraldehyde-3-phosphate pool and effects intracellular phosphate fixation in the form of 2-deoxyglucose 6-phosphate, but the cytosolic phosphorylation potential is not increased and reperfusion failure occurs instantly. (4) Consistent correlations exist between cytosolic ATP phosphorylation potential and reperfusion contractile function. The findings depict glycolysis as a highly adaptive emergency mechanism which can prevent deleterious myocyte deenergization during forced ischemia-reperfusion transitions in presence of excess oxidative substrate.
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PMID:Glucose requirement for postischemic recovery of perfused working heart. 231 14

Pyruvate dehydrogenase complex (PDHC) is a major enzyme of glucose metabolism. Dichloroacetate (DCA) is a noncompetitive inhibitor of PDHC kinase, an enzyme that inactivates PDHC. We examined the effects of DCA on extracellular lactate and pyruvate concentration changes and spinal somatosensory evoked potentials (SSEP) in ischemic rabbit spinal cords. In the first group of 26 animals, the aorta was occluded until postsynaptic SSEP waves were completely suppressed for 10 min, a period of ischemia that causes neurologic deficits in 50% of untreated animals. DCA (25 mg/kg) was given to 13 of these animals before ischemia. In the second group of 24 animals, the aorta was occluded until the postsynaptic SSEP waves were absent for 20 min, a period of ischemia that produces paraplegia in 100% of untreated animals. DCA (25 mg/kg) was given to 16 of these animals just before the aortic occlusion was released. After occlusion, extracellular spinal lactate concentrations increased abruptly while pyruvate concentrations fell. Both lactate and pyruvate concentrations reached a plateau during the ischemic period but increased when the aortic balloon was deflated. DCA-treated animals had lower lactate and pyruvate peak concentrations during reperfusion, as well as more rapid and greater recovery of SSEP at 2 h after reperfusion. DCA did not alter spinal metabolism during the ischemia but appeared to produce a more rapid shift to glucose metabolism on reperfusion. Thus, DCA treatment resulted in better electrophysiological recovery after both moderate and severe ischemia, either by reducing lactic acidosis or by increasing the recovery rate of aerobic energy production.
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PMID:Reduction in spinal cord postischemic lactic acidosis and functional improvement with dichloroacetate. 234 14

Hyperglycemia has been shown to exacerbate neurological deficit associated with central nervous system ischemia. Iodoacetate or dichloroacetate was administered intraperitoneally to rats in a study to examine the role of glycolysis in hyperglycemic exacerbation of neurological deficit. Sprague-Dawley rats were injected with saline, iodoacetate, or dichloroacetate and then made paraplegic by temporary occlusion for 10, 12, 13, or 15 minutes of the right and left subclavian arteries and the aorta distal to the left subclavian artery. Glycolytic blockage by iodoacetate was lethal in doses of 15 mg/kg or more, whereas rats receiving 10 mg/kg survived but showed no significant neurological improvement compared to the saline-treated control group. Dichloroacetate, 500 mg/kg, protected neurological function, which suggests a possible detrimental role for lactate accumulation and the benefit of maintaining tricarboxylic acid cycle activity by stimulating pyruvate dehydrogenase. The protection seen with dichloroacetate depended on the severity of ischemic injury. Dichloroacetate administration had a minimal effect on neurological outcome with occlusion periods of 13 and 15 minutes, mild improvement with 12 minutes of occlusion, and a significant protective effect with a 10-minute occlusion period. The dose-response nature of ischemic injury and neurological outcome in this rat model of paraplegia therefore appears to play an important role in determining the effect observed with a specific intervention.
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PMID:Neurological protection by dichloroacetate depending on the severity of injury in the paraplegic rat. 235 11

The effect of cerebral ischemia on the activity of pyruvate dehydrogenase (PDH) enzyme complex (PDHC) was investigated in homogenates of frozen rat cerebral cortex following 15 min of bilateral common carotid occlusion ischemia and following 15 min, 60 min, and 6 h of recirculation after 15 min of ischemia. In frozen cortical tissue from the same animals, the levels of labile phosphate compounds, glucose, glycogen, lactate, and pyruvate was determined. In cortex from control animals, the rate of [1(-14)C]pyruvate decarboxylation was 9.6 +/- 0.5 nmol CO2/(min-mg protein) or 40% of the total PDHC activity. This fraction increased to 89% at the end of 15 min of ischemia. At 15 min of recirculation following 15 min of ischemia, the PDHC activity decreased to 50% of control levels and was depressed for up to 6 h post ischemia. This decrease in activity was not due to a decrease in total PDHC activity. Apart from a reduction in ATP levels, the acute changes in the levels of energy metabolites were essentially normalized at 6 h of recovery. Dichloroacetate (DCA), an inhibitor of PDH kinase, given to rats at 250 mg/kg i.p. four times over 2 h, significantly decreased blood glucose levels from 7.4 +/- 0.6 to 5.1 +/- 0.3 mmol/L and fully activated PDHC. In animals in which the plasma glucose level was maintained at control levels of 8.3 +/- 0.5 mumol/g by intravenous infusion of glucose, the active portion of PDHC increased to 95 +/- 4%. In contrast, the depressed PDHC activity at 15 min following ischemia was not affected by the DCA treatment.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Pyruvate dehydrogenase activity in the rat cerebral cortex following cerebral ischemia. 271 7

Ischemic dysfunction, including contracture, has been attributed to lack of ATP, although previous work has not been consistent with this concept. We describe here a model of no flow ischemic arrest, characterized by depressed levels of mechanical function upon reperfusion and high energy phosphate stores within normal limits. The decreased mechanical function bears an inverse relationship to myocardial lactate levels after twenty-minutes of reperfusion in the absence or presence of dichloroacetic acid (DCA). Post-ischemic non-DCA treated hearts attained peak work of only 25% of that of controls, while those treated with DCA following ischemia performed almost as well as controls. ATP and CP levels remained high in both DCA treated and non-DCA treated hearts. Lactate levels were high in hearts immediately following ischemia, but were reduced to control levels in post-ischemic hearts perfused with DCA within twenty minutes, whereas those not treated with DCA had lactate levels two to three times that of controls within the same time period. Pyruvate dehydrogenase (PDH) activity was reduced in non-DCA treated post ischemic hearts after twenty minutes reperfusion but was elevated above controls in hearts reperfused with DCA. The data indicates that DCA increases mechanical performance of the isolated post-ischemic rat heart and the proposed mechanism for this increase is the oxidative removal of lactate resulting from an increase in PDH activity.
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PMID:The effect of dichloroacetate on the isolated no flow arrested rat heart. 274 13

Dichloroacetate (DCA) is known to prevent the phosphorylation of the pyruvate dehydrogenase complex (PDHC) by blocking the action of PDH kinase. This action allows the active PDHC to exert its effect on the metabolism of glucose, lactate and alanine to acetyl CoA. DCA has been shown to reduce serum lactate levels in humans and animals in such conditions as diabetes, phenformin-induced hepatic failure, exercise, and endotoxin-induced shock. Lactic acidosis in the brain has often been postulated as a cause of neuronal damage following ischemia and hypoxia. Therefore, we examined the effect of intravenously administered DCA (100 mg/kg) in rats that were rendered hyperglycemic by intravenous glucose (2 g/kg), and then made to undergo 15 minutes of incomplete cerebral ischemia by bilateral carotid ligation and systemic hypotension (mean arterial pressure of 50 mm Hg). DCA significantly reduced serum lactate levels pre-ischemia, but had no effect on serum lactate levels after ischemia induction. Brain levels of lactate, ATP and PCr after 15 minutes of incomplete ischemia were unaffected by DCA. We conclude that in this in-vivo model the control of PDHC activity in the brain may be different than that in the periphery, and that DCA was not effective in reducing brain tissue lactate levels.
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PMID:The effect of dichloroacetate on brain lactate levels following incomplete ischemia in the hyperglycemic rat. 371 55

Dichloroacetate facilitated a reduction in brain lactate following ischemia in the gerbil. This treatment also improved high-energy metabolite and pyruvate dehydrogenase enzyme recovery. The purpose of this study was to determine the effect of dichloroacetate on ischemia-induced neuronal damage in the hippocampus of the gerbil. In adult male gerbils, carotid arteries were clamped bilaterally for 5 min. After ischemia, each gerbil was graded neurologically and received an ip injection of dichloroacetate (75 or 225 mg/kg) or an equal volume (5 mL/kg) of sodium acetate (66 mg/kg). On the following morning, gerbils received a second injection, and 3 d later were anesthetized and perfused intracardially. Brains were processed, and stained sections were analyzed for neuronal damage. Gerbils treated with 225 mg/kg dichloroacetate exhibited significantly less damage than the untreated group (p = 0.05, Dunn's test). Gerbils with a normal neurologic score evidenced no neuronal damage. Abnormal neurologic scores immediately after ischemia did not correlate with degree of neuronal damage observed 4 d later. These results indicate that neuronal damage is less in gerbils treated after ischemia with an appropriate dose of dichloroacetate. The lack of any histological evidence for an adverse effect of dichloroacetate in the controls supports the safety of this drug in this protocol. Normal neurologic scores immediately after ischemia can be used to identify gerbils mimicking ischemia in this model.
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PMID:Dichloroacetate attenuates neuronal damage in a gerbil model of brain ischemia. 771 Sep 22

Increased carbohydrate utilization may protect the heart during ischemia and reperfusion. Dichloroacetate (DCA) stimulates pyruvate dehydrogenase, which is the rate-limiting step in oxidation of lactate and pyruvate. The purpose of this study was to determine if the myocardial metabolic changes induced by intracoronary DCA during myocardial ischemia were accompanied by improvement in systolic function. A perfusion circuit was created from the carotid to left anterior descending coronary artery (LAD) in 11 anesthetized Yorkshire swine. Data were obtained under strict hemodynamic control at baseline, after 15 min of moderate (30%) LAD flow reduction, and after an additional 15 min of ischemia with either intracoronary DCA (3 mM, n = 6) or saline (n = 5) infusion. DCA decreased lactate release and increased lactate uptake during ischemia as measured by glucose and lactate carbon-labeled tracers. Despite these metabolic changes, no improvement in systolic shortening, microsphere blood flow, or oxygen consumption occurred. Thus, although DCA stimulated carbohydrate metabolism during myocardial ischemia, it did not directly improve systolic function.
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PMID:Dichloroacetate stimulates carbohydrate metabolism but does not improve systolic function in ischemic pig heart. 786 15

High levels of fatty acids can decrease the recovery of previously ischemic hearts by inhibiting myocardial glucose use during reperfusion. We determined if this was due to a decrease in glycolysis or a decrease in glucose oxidation. Isolated working rat hearts were perfused with either 11 mM [2-3H/U-14C] glucose or 11 mM [2-3H/U-14C] glucose and 1.2 mM palmitate. In aerobically perfused hearts, the presence of fatty acids reduced glucose oxidation rates (from 1576 +/- 154 to 228 +/- 28 nmol/min.g dry weight, P < .05), with a nonsignificant reduction in glycolysis (from 3297 +/- 349 to 2798 +/- 343 nmol/min.g dry weight). If fatty acid perfused hearts were subjected to a 30-min period of ischemic function was 36%. Glucose oxidation rates during reperfusion were markedly lower than glycolytic rates (228 +/- 35 and 3096 +/- 576 nmol/min.g dry weight, respectively, P < .05). Dichloroacetate (1 mM) added during reperfusion significantly improved recovery of mechanical function to 96% of preischemic values. In these hearts, Dichloracetate increased glucose oxidation, while actually decreasing glycolytic rates (values during reperfusion were 501 +/- 136 and 1171 +/- 122 nmol/min.g dry weight, respectively). Insulin (500 microU/ml) added at reperfusion resulted in a small increase in glucose oxidation rates and a significant increase in glycolysis (375 +/- 66 and 4769 +/- 955 nmol/g dry weight.min, respectively). However, the presence of insulin at reperfusion did not improve recovery of function (hearts recovered 52% of preischemic function). We demonstrate that the detrimental effects of high concentrations of fatty acids after ischemia are primarily due to an inhibition of glucose oxidation, and not glycolysis, during the reperfusion period. Furthermore, increasing glucose oxidation during reperfusion has a beneficial effect on functional recovery of hearts.
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PMID:An imbalance between glycolysis and glucose oxidation is a possible explanation for the detrimental effects of high levels of fatty acids during aerobic reperfusion of ischemic hearts. 838 Aug 56


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