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)

Electron transport in tissue cubes, isolated mitochondria and submitochondria particles were examined as a function of ischemic time. It was found that electron transport remains active in all systems beyond the 2 hour ischemic time interval. The NADH stimulated respiration, however, declined after 2 hours of ischemia in ASU (Ammonia-Sephadex-Urea) particles followed by respiration with matrix-located dehydrogenases tested by substrates such as glutamate, alpha-ketoglutarate and pyruvate plus malate. Succinate dependent respiration remains active at control levels. In contrast proton gradient reveals changes in two phases: Phase A is characterized by gradually increasing gradient without valinomycin and by a rapidly declining gradient with valinomycin in the medium. Phase B is characterized by a declining proton gradient with or without valinomycin. It is suggested that the alteration of the proton gradient between 1 and 2 hours ischemia is an important factor contributing to irreversible cell injury.
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PMID:Studies on the pathogenesis of ischemic cell injury. VII. Proton gradient and respiration of renal tissue cubes, renal mitochondrial and submitochondrial particles following ischemic cell injury. 60 84

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

AMP deaminase, which hydrolyses AMP to inosine 5'-monophosphate (IMP) and NH3 at high rates during excessive energy demands in skeletal muscle, is activated when bound to myosin in vitro. We evaluated AMP deaminase binding in vivo during muscle contractions to assess whether binding 1) is inherent to deamination and found only with high rates of IMP production or simply coincident with the contractile process and 2) requires cellular acidosis. AMP deaminase activity (mumol.min-1.g-1) was measured in the supernatant (free) and 10(4)-g pellet (bound) homogenate fractions of muscle of anesthetized rats after in situ contractions to determine the percent bound. In resting muscle, nearly all (approximately 90%) AMP deaminase is free (cytosolic). During contractions when energy balance was well maintained, binding did not significantly differ from resting values. However, during intense contraction conditions that lead to increased IMP concentration, binding increased to approximately 60% (P less than 0.001) in fast-twitch and approximately 50% in slow-twitch muscle. Binding increased in an apparent first-order manner and preceded initiation of IMP formation. Further, binding rapidly declined within 1 min after cessation of intense stimulation, even though the cell remained extremely acidotic. Extensive binding during contractions was also evident without cellular acidosis (iodoacetic acid-treated muscle). Thus the in vivo AMP deaminase-myosin complex association/dissociation is not coupled to changes in cellular acidosis. Interestingly, binding remained elevated after contractions, if energy recovery was limited by ischemia. Our results are consistent with myosin binding having a role in AMP deaminase activation and subsequent IMP formation in contracting muscle.
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PMID:AMP deaminase binding in contracting rat skeletal muscle. 151 75

Lipocortin-1 (annexin-1) is an endogenous peptide with antiinflammatory properties. We have previously demonstrated lipocortin immunoreactivity in certain glial cells and neurons in the rat brain (Strijbos, P.J.L.M., F.J.H. Tilders, F. Carey, R. Forder, and N.J. Rothwell. 1990. Brain Res. In press.), and have shown that an NH2-terminal fragment (1-188) of lipocortin-1 inhibits the central and peripheral actions of cytokines on fever and thermogenesis in the rat in vivo (Carey, F., R. Forder, M.D. Edge, A.R. Greene, M.A. Horan, P.J.L.M. Strijbos, and N.J. Rothwell. 1990. Am. J. Physiol. 259:R266; and Strijbos, P.J.L.M., J.L. Browning, M. Ward, R. Forder, F. Carey, M.A. Horan, and N.J. Rothwell. 1991. Br. J. Pharmacol. In press.). We now report that intracerebroventricular administration of lipocortin-1 fragment causes marked inhibition of infarct size (60%) and cerebral edema (46%) measured 2 h after cerebral ischemia (middle cerebral artery occlusion) in the rat in vivo. The lipocortin-1 fragment was effective when administered 10 min after induction of ischemia. Ischemia caused increased expression of lipocortin-1 around the area of infarction as demonstrated by immunocytochemistry. Intracerebroventricular injection of neutralizing antilipocortin-1 fragment antiserum increased the size of infarct (53%) and the development of edema (29%). These findings indicate that lipocortin-1 is an endogenous inhibitor of cerebral ischemia with considerable therapeutic potential.
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PMID:Lipocortin-1 is an endogenous inhibitor of ischemic damage in the rat brain. 183 Mar 27

The human heart in the fasting state extracts free fatty acids (FFA), glucose, lactate, pyruvate, and ketones from circulating blood. The utilization of FFA accounts for most of the oxygen consumed and energy produced at rest. Patients with angiographically demonstrable coronary artery disease and stable angina pectoris have a resting myocardial metabolism similar to that of normal individuals. During atrial pacing in normal persons, there is a significant enhancement of glucose uptake but that of FFA is unchanged, and the oxidation of carbohydrates accounts for more than 60% of the energy produced. In patients with stable angina, myocardial perfusion becomes regionally inadequate during stress. Despite the increase of myocardial glucose utilization, carbohydrate oxidation is negligible. Pyruvate will not be oxidized but in the presence of increased amounts of reduced coenzymes will be reduced to lactate. In addition, a greater amount of alanine will be released by the myocardium through the transamination of pyruvate, with a concomitantly greater uptake of glutamate that serves as the NH2 donor. In addition, glutamate may be used as an anaerobic fuel through conversion to succinate coupled with GTP formation. Although coronary hemodynamics, including myocardial perfusion, return to baseline within a few minutes after stress, a longer time course is needed for myocardial metabolism to become normal. In particular, myocardial utilization of exogenous glucose remains higher well after the normalization of hemodynamic parameters. This is more pronounced in postischemic myocardium, but it also occurs in nonischemic muscle, and glucose is presumably used for rebuilding glycogen stores that were depleted during ischemia.
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PMID:Metabolic markers of stress-induced myocardial ischemia. 202 52

After portacaval shunt in the rat, the transport of tryptophan and other neutral amino acids across the blood-brain barrier is enhanced. To determine the role of NH3 in the intracerebral transfer of tryptophan and serotonin metabolism, solutions containing either saline or NH3 or tryptophan or NH3 + tryptophan together were infused, respectively, into the internal carotid artery of rats in order to achieve blood levels similar to those observed after liver ischemia. After tryptophan infusion, a significant increase in the hypothalamic levels of tryptophan and 5-hydroxyindoleacetic acid was observed. A similar increment was found after NH3 infusion. NH3 + tryptophan infusion induced a significant increment in hypothalamic tryptophan and 5-hydroxyindoleacetic acid levels which were 2-fold greater than after tryptophan infusion. There was no significant change in 5-hydroxytryptamine levels in any of these experiments. Glutamine levels increased significantly after NH3 infusion. When tryptophan and NH3 were infused simultaneously, a significant reduction in glutamine levels occurred. These results cannot be explained by any modification of cerebral blood flow nor of the cerebral intercellular pH. Our data suggest that NH3 enhances the transfer of tryptophan across the blood-brain barrier and thus stimulates serotonin metabolism. The mechanism by which tryptophan transfer across the blood-brain barrier is facilitated is unknown. The reduction in glutamine levels in the hypothalamus when NH3 and tryptophan are infused together may be explained either by an inhibition of synthesis or by an intercellular influx of neutral amino acids and an efflux of glutamine as suggested by James et al.
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PMID:Evidence for the role of ammonia in the intracerebral transfer and metabolism of tryptophan. 242 70

The potential therapeutic value of the chemically stable carbacyclin analogue iloprost on the course of postischemic acute renal failure was studied in six conscious chronically instrumented dogs and compared with five controls. Immediately after temporary ischemia (180-min cessation of blood flow by inflation of a pneumatic cuff), the investigational group PC received a continuous intraaortal infusion of iloprost (50 ng X min-1 X kg-1) over a period of seven days, whereas the control group C received 0.9% saline. The glomerular filtration rate [( 51Cr]EDTA clearance, endogenous creatinine clearance) was less decreased in the prostacyclin analogue group than in the control group [3rd day, 18 +/- 2.5 vs. 12 +/- 1 ml X min-1 (p less than 0.05); 7th day, 23 +/- 3 vs. 12 +/- 2 ml X min-1 (p less than 0.05)]. On day 1, renal blood flow (electromagnetic flow probe) was markedly lower in the control group (129 +/- 29 ml X min-1) than in the PC group (212 +/- 29 ml X min-1; p less than 0.05), even exceeding baseline levels in the latter group. Accordingly, the excessive rise in renal vascular resistance in the control group (+136%) was abolished in the PC group (-32%; p less than 0.01). Nitrogen retention was also markedly improved. Osmolar clearance was markedly lower in the control group (0.58 +/- 0.2 ml X min-1) than in the PC group (1.41 +/- 0.17 ml X min-1; p less than 0.05). It is suggested that the beneficial effect of iloprost is mediated by preservation of renal perfusion.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Amelioration of postischemic acute renal failure by prostacyclin analogue (iloprost): long-term studies with chronically instrumented conscious dogs. 242 19

The human heart in the fasting state extracts FFA, glucose, lactate, pyruvate, and ketone bodies from the systemic circulation. Of these substrates, FFA utilization accounts for the greater part of oxygen consumption and energy production. The oxidative use of lipid (FFA) and carbohydrate (glucose and lactate) fuels is reciprocally regulated through the operation of Randle's cycle. Feeding, by increasing both insulin and glucose concentration, shifts myocardial metabolism towards preferential carbohydrate usage, both for oxidative energy generation and for glycogen synthesis. During conditions of reduced oxygen supply, the oxidation of all substrates is decreased while anaerobic metabolism is activated. In patients with coronary artery disease and stable angina pectoris, lactate release in the CS can be demonstrated during pacing stress. However, this occurs in only 50% of patients, and no relationship can be demonstrated between lactate production and the severity of ischemia. In patients with chronic angina, a significant release of alanine in the CS and an increased myocardial uptake of glutamate could be demonstrated at rest and following pacing. These two phenomena result from increased transamination of excess pyruvate to alanine with glutamate serving as NH2 donor. In addition, release of citrate (a known inhibitor of glycolysis) in the CS can be demonstrated following pacing in patients with stable angina. The introduction of PET has made it possible to study regional myocardial perfusion and metabolism in humans noninvasively. Two basically different patterns of myocardial glucose utilization have been observed in patients with coronary artery disease studied at rest using 18F-flurodeoxyglucose. In patients with stable angina on exercise but studied at rest, regional myocar- dial glucose utilization was homogeneously low and comparable with that of a group of normals. In contrast, in patients with unstable angina, myocardial glucose utilization at rest was increased even in the absence of symptoms and ECG signs of acute ischemia. In patients with stable angina, a prolonged increase in glucose uptake could be demonstrated in the post-ischemic myocardium in the absence of perfusion abnormalities, and a state of chronic metabolic ischemia is proposed. PET imaging has also allowed prospective differentiation between viable and nonviable segmental function in patients with recent myocardial infarction and in those undergoing coronary artery surgery; in both cases viable segments have relatively maintained glucose uptakes, whereas nonviable segments have depressed glucose uptakes.
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PMID:Myocardial metabolism in ischemic heart disease: basic principles and application to imaging by positron emission tomography. 268 79

To evaluate myocardial blood flow and glucose utilization, N-13 ammonia (NH3) and F-18 deoxyglucose positron emission tomography scanning was performed in 22 patients with previous anterior wall myocardial infarction, using a high-resolution, multi-slice, whole-body scanner. The N-13 ammonia study was performed at rest and after exercise. The F-18 deoxyglucose study was performed at rest after fasting greater than 5 hours. The N-13 ammonia study revealed a hypoperfused area in 19 of the 22 patients (86%), that corresponded to the infarcted regions as diagnosed by electrocardiography, coronary arteriography and left ventriculography (21 patients). The hypoperfused areas expanded after exercise in 16 of 22 patients (73%). F-18 deoxyglucose uptake was observed in these hypoperfused areas, especially in patients with hypokinetic wall motion on left ventriculography and in exercise-induced hypoperfused areas. However, positron emission tomography demonstrated diffuse uptake of F-18 deoxyglucose in 3 of 8 patients with dyskinetic wall motion. Thus, metabolically active myocardium in infarcted areas or periinfarct ischemia can be visualized with F-18 deoxyglucose and stress N-13 ammonia studies.
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PMID:F-18 deoxyglucose and stress N-13 ammonia positron emission tomography in anterior wall healed myocardial infarction. 325 30

The decrease in myocardial contractility during ischemia, hypoxia, and extracellular acidosis has been attributed to intracellular acidosis. Previous studies of the relationship between pH and contractile state have utilized respiratory or metabolic acidosis to alter intracellular pH. We developed a model in the working perfused rat heart to study the effects of intracellular acidosis with normal external pH and optimal O2 delivery. Intracellular pH and high-energy phosphates were monitored by 31P nuclear magnetic resonance spectroscopy. Hearts were perfused to a steady state with a medium containing 10 mM NH4Cl (extracellular pH, 7.4). The subsequent washout of NH3 from the cytosol generated a slight acidosis (from intracellular pH 7.0 to 6.8) which was associated with little change in the determinants of O2 consumption (rate-pressure product) and O2 delivery (coronary flow). Acidosis induced a substantial decrease in aortic flow and stroke volume which was associated with little change in peak systolic pressure. Results were qualitatively similar at different external [Ca2+] (1.75, 2.5, 3.15 mM) and preload (12 or 21 cmH2O) but were most prominent at the lowest external [Ca2+] and left atrial pressure. In contrast to this model of isolated intracellular acidosis, hearts subject to a respiratory (extracellular plus intracellular) acidosis showed a marked reduction in pressure development. It was concluded that 1) for the same intracellular acidosis the influence on tension development was more pronounced with a combined extra- and intracellular acidosis than with an isolated intracellular acidosis, and 2) stroke volume at constant preload was impaired by intracellular acidosis even though changes in developed pressure were minimal. These observations suggest that isolated intracellular acidosis has adverse effects on diastolic compliance and/or relaxation.
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PMID:Influence of intracellular acidosis on contractile function in the working rat heart. 342 50

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