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)

A uniform, predictable pattern of cellular abnormalities is seen after complete, irreversible ischemic injury to the central nervous system. This is in contrast to the heterogeneous, multifocal picture which characterizes incomplete ischemia. The range of abnormalities in neuronal soma after an arterial occlusion changes considerably as a function of time and site. There is no single pattern of neuronal alteration that can be ascribed exclusively to ischemia. Red neurons are a relatively late (about 18 h) indicator of ischemia and are seen only in areas where blood supply is marginal. In addition to depletion of high-energy-phosphate reserves, brain ischemia results in characteristic alterations of amino acid concentrations in the ischemic tissue. Glutamate, glutamine, and aspartate either decrease or remain constant while alanine increases. Proportional decreases in the former three amino acids may be explained by simple dilution due to edema. Increases in alanine relative to glutamate and aspartate may be utilized as a biochemical index of perfusion to various brain regions.
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PMID:Neuronal ischemic injury: light microscopy, ultrastructure and biochemistry. 9 17

Tracer kinetic studies on the effect of i.v. infused adrenaline and angiotensin, and a hyperglycemia induced by glucose application, upon glucose metabolism of the rat brain under ischemic and normoxic conditions are reported. in the ischemic brain, the initial glycolytic rate proved dependent on the glucose content being kept at various levels by glucose administration or hormone infusion prior to the onset of ischemia. The typical saturation kinetics revealed a maximal glucose conversion only from a definite initial content of brain glucose, being equivalent to a glucose level of approximately 13 mumole/ml in plasma, and appeared to depend on the presence of glucose in the cellular space. The early cessation of anaerobic lactate formation even with high glucose in the cellular space. The early cessation of anaerobic lactate formation even with high glucose depot in the brain tissue is referred to inhibition of glycolytic key enzymes by increasing tissue azidosis. The aerobic glucose conversion, as calculated from the Cglucose flux in amino acids associated with the citrate cycle was unaffected by the cerebral glucose content (hyperglycemia by hormone or glucose application). During glucose infusion the cerebral levels of NH3, total NH2 and glutamine rose; the Cglucose flux into aspartate and glutamine was increased and almost proportionally reduced in glutamate and gamma-aminobutyrate. These flux shifts are interpreted as a switching of C-chains from pyruvate owing to increased CO2 fixation, and as a biochemical correlate of an increased irritation level of the experimental animals.
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PMID:[Effect of increased plasma levels of glucose, adrenaline, and angiotensin upon glucose metabolism of totally ischemic and normally perfused rat brain]. 123 36

In normal rats, muscle is the major glutamine releasing organ and gut is the major glutamine consuming organ. It has been suggested that enhanced muscle ammonia detoxification and gut ammonia production occurs during liver insufficiency-induced hyperammonemia. Therefore, ammonia and amino acid fluxes across portal-drained viscera and hindquarter, and muscle concentrations were measured in portacaval shunted and acute liver ischemia rats. Arterial ammonia and most amino acids were increased after portacaval shunting and increased progressively during liver ischemia, but net hindquarter ammonia uptake was not observed. Net hindquarter glutamine efflux was increased during portacaval shunting, but it decreased during liver ischemia, while muscle glutamine concentrations increased. The comparable net portal drained viscera glutamine uptake in normal and portacaval shunted rats changed during liver ischemia from net uptake to release, coinciding with release of most other amino acids. These results cast doubt on the ammonia detoxifying role of muscle during acute liver ischemia-induced hyperammonemia in the rat. The portal drained viscera glutamine release during severe hyperammonemia could be due to intestinal damage.
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PMID:Altered glutamine metabolism in rat portal drained viscera and hindquarter during hyperammonemia. 134 32

The extracellular concentrations of aspartate, glutamate, glutamine, taurine and gamma-aminobutyric acid in the hippocampus were determined during and after forebrain ischemia (4-vessel model) in the unanaesthetized rat. Ischemia led to a large increase in both inhibitory (taurine and gamma-aminobutyric acid) and excitatory amino acids (aspartate, glutamate). These results suggest that in this model, as previously proposed in other models of ischemia, the large increase of inhibitory amino acids could counterbalance the excitotoxicity due to aspartate and glutamate.
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PMID:Concomitant increases in the extracellular concentrations of excitatory and inhibitory amino acids in the rat hippocampus during forebrain ischemia. 135 33

Hyperammonemia has been suggested to induce enhanced cerebral cortex ammonia uptake, subsequent glutamine synthesis and accumulation, and finally net glutamine release into the blood stream, but this has never been confirmed in liver insufficiency models. Therefore, cerebral cortex ammonia- and glutamine-related metabolism was studied during liver insufficiency-induced hyperammonemia by measuring plasma flow and venous-arterial concentration differences of ammonia and amino acids across the cerebral cortex (enabling estimation of net metabolite exchange), 1 day after portacaval shunting and 2, 4, and 6 h after hepatic artery ligation (or in controls). The intra-organ effects were investigated by measuring cerebral cortex tissue ammonia and amino acids 6 h after liver ischemia induction or in controls. Arterial ammonia and glutamine increased in portacaval-shunted rats versus controls, and further increased during liver ischemia. Cerebral cortex net ammonia uptake, observed in portacaval-shunted rats, increased progressively during liver ischemia, but net glutamine release was only observed after 6 h of liver ischemia. Cerebral cortex tissue glutamine, gamma-aminobutyric acid, most other amino acids, and ammonia levels were increased during liver ischemia. Glutamate was equally decreased in portacaval-shunted and liver-ischemia rats. The observed net cerebral cortex ammonia uptake, cerebral cortex tissue ammonia and glutamine accumulation, and finally glutamine release into the blood suggest that the rat cerebral cortex initially contributes to net ammonia removal from the blood during liver insufficiency-induced hyperammonemia by augmenting tissue glutamine and ammonia pools, and later by net glutamine release into the blood. The changes in cerebral cortex glutamate and gamma-aminobutyric acid could be related to altered ammonia metabolism.
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PMID:Cerebral cortex ammonia and glutamine metabolism during liver insufficiency-induced hyperammonemia in the rat. 149 99

Initial function of the graft is an essential factor for successful liver transplantation. The aim of this study was to evaluate the influence of the nutritional status of the donor on hepatic graft quality at reperfusion. Livers (n = 41) were taken from pigs normally fed or fasted for 24 h or fasted for 24 h and conditioned for 2 hours with a solution containing glucose, fructose and glutamine. The quality of liver grafts was evaluated using an original, blood-free isolated perfusion model, after 8 h cold storage, or after 15 min warm ischemia performed prior to harvesting. The hepatic concentration of glycogen and ATP, measured from in vivo biopsies, was decreased in fasted animals (P less than 0.05 vs fed) and restored by nutritional conditioning (P less than 0.05 vs fasted). At the time of reperfusion following 8 h cold ischemia, the liberation of aminotransferases and lactate dehydrogenase was elevated in livers coming from fasted animals (P less than 0.05 vs fed) and restored to fed levels after nutritional conditioning (P less than 0.01 vs fasted). After 15 min of warm ischemia, the bile secretion during the reperfusion period was decreased in the 24 h fasted livers (P less than 0.01 vs fed) and reestablished after nutritional conditioning (P less than 0.01 vs fasted). Perfusion of the donor liver, in the 2 h preceding harvest, with a solution of glucose plus neoglucogenic precursors enhances the quality of the liver graft at the time of reperfusion.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Effect of nutritional status of the donor on the quality of hepatic graft. Value of restoration of glycogenic reserves of the donor]. 152 97

Renal metabolism has been studied in eight dogs before and 48 hr after a 60-min period of renal ischemia induced by clamping the left renal artery with the simultaneous removal of the right kidney, and in 12 sham-operated animals. The study involved the measurement of renal uptake and production of lactate, glutamine, glutamate, alanine, ammonium, and oxygen, and the measurement of the tissue concentrations of ATP, glutamine, lactate, alpha-ketoglutarate, aspartate, and alanine in the renal cortex. Two days after a temporary renal ischemia, the remaining kidney showed a 22% decrease in glomerular filtration rate (GFR) and a 25% decrease in renal plasma flow. Fractional sodium and potassium excretions were similar to those of control dogs. Renal production or extraction of glutamine, glutamate, alanine, ammonium, and oxygen (all expressed by 100 ml of GFR) was not significantly different in basal conditions or 2 days after ischemia, but lactate extraction was reduced in postischemic kidneys (-101 +/- 29 vs -204 +/- 38 mumol/100 ml GFR in control dogs). The cortical concentrations of glutamine and glutamate were lower in postischemic than in control kidneys. No differences were found in cortical concentration of alpha-ketoglutarate, aspartate, lactate, pyruvate, or ATP, but total nucleotides and inorganic phosphate were decreased in postischemic kidneys. It is concluded that in the recovery phase of the ischemia, a decreased lactate uptake is the main metabolic change, and total ATP production is adapted to the decrease of GFR and sodium reabsorption.
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PMID:Renal cortical intermediary metabolism in the recovery phase of postischemic acute renal failure in the dog. 153 34

Both increased gamma-aminobutyric acid (GABA)-ergic and decreased glutamatergic neurotransmission have been suggested relative to the pathophysiology of hepatic encephalopathy. This proposed disturbance in neurotransmitter balance, however, is based mainly on brain tissue analysis. Because the approach of whole tissue analysis is of limited value with regard to in vivo neurotransmission, we have studied the extracellular concentrations in the cerebral cortex of several neuroactive amino acids by application of the in vivo microdialysis technique. During acute hepatic encephalopathy induced in rats by complete liver ischemia, increased extracellular concentrations of the neuroactive amino acids glutamate, taurine, and glycine were observed, whereas extracellular concentrations of aspartate and GABA were unaltered and glutamine decreased. It is therefore suggested that hepatic encephalopathy is associated with glycine potentiated glutamate neurotoxicity rather than with a shortage of the neurotransmitter glutamate. In addition, increased extracellular concentration of taurine might contribute to the disturbed neurotransmitter balance. The observation of decreasing glutamine concentrations, after an initial increase, points to a possible astrocytic dysfunction involved in the pathophysiology of hepatic encephalopathy.
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PMID:Amino acid release from cerebral cortex in experimental acute liver failure, studied by in vivo cerebral cortex microdialysis. 162 30

Using in vivo 1H NMR spectroscopy (1H MRS) and biochemical analysis, the effects of hyperammonemia on cerebral function were studied in three rat models: acute liver ischemia (LIS), administration of urease (UREASE) and administration of methionine sulfoximine (MSO). By means of localization in three dimensions signals were obtained exclusively from the cerebral cortex. Specially developed lineshape correction and fitting methods were used to quantitate the MRS signals. The following concentration changes were observed; a decrease in glutamate and (phospho)choline for all the models; an increase in glutamine in the LIS and UREASE model but a decrease in the MSO model; a marked increase in lactate in the LIS and UREASE group; a tendency to a decrease in N-acetylaspartate in all the models. These changes agree well with the changes in the post-mortem biochemically determined cerebral cortex glutamine and glutamate concentrations. Estimated absolute 1H MRS metabolite concentrations agree well with those obtained by other techniques; cerebral cortex glutamate, however, is underestimated by about 35% by NMR. The present data support the hypothesis that hyperammonemia is associated with a decreased availability of glutamate for neurotransmission.
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PMID:The use of in vivo proton NMR to study the effects of hyperammonemia in the rat cerebral cortex. 167 7

Excitatory (glutamate, aspartate) or inhibitory amino acids (gamma-aminobutyric acid: GABA, taurine) and glutamine contents were examined in acutely induced cerebral ischemia in spontaneously hypertensive rats. At 20 min ischemia most of these amino acids remained unchanged, but glutamine significantly decreased by 14% in the CA3 hippocampal subfield. At 60 min ischemia glutamate significantly decreased by 14% in the CA3, aspartate by 17-26% in the CA3, cingulate cortex, septum and striatum. In contrast, GABA significantly increased by 48-106% in the cortices (frontal, parietal and cingulate), striatum and nucleus accumbens, but insignificantly in hippocampal subfields. Likewise, taurine increased in the parietal cortex and nucleus accumbens. Glutamine showed heterogeneous changes (increase in the nucleus accumbens and decrease in the CA3). Amino acid levels change during ischemia, but their changes are varied in each area, implying that different reaction of amino acids may explain the selective vulnerability to cerebral ischemia.
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PMID:Excitatory and inhibitory amino acid changes in ischemic brain regions in spontaneously hypertensive rats. 167 76

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