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

We studied changes in myofibrillar function and protein profiles after complete global ischemia with anoxia in rat hearts. Hearts were exposed to global ischemia and anoxia (CGI) for 30 or 60 minutes at 37 degrees C, and myofibrils were prepared for measurement of Ca(2+)-dependent Mg(2+)-ATPase activity at pH 7.0 and 6.5. Hearts incubated in cold saline (1 +/- 1 degrees C) and nonincubated hearts served as controls. Maximum ATPase activity was unchanged at pH 7.0 and pH 6.5 in myofibrils from hearts treated with 30 or 60 minutes of CGI. At pH 7.0, the Hill coefficient, which is an index of cooperative interactions among thin-filament proteins, was unchanged after 30 minutes of CGI but was significantly increased after 60 minutes of CGI. A similar trend for increased cooperativity was observed when myofibrillar ATPase activity was measured at pH 6.5 in myofibrils from rat hearts made ischemic for 30 or 60 minutes. Both 30 and 60 minutes of CGI resulted in increased pCa50 values (half-maximally activating free [Ca2+]) at pH 7.0 and pH 6.5. Densitometric analysis of myofibrillar proteins separated with sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that troponin I and troponin T were degraded during 60 minutes of CGI. Two new protein bands appearing in ischemia-treated myofibrils were identified as partially degraded troponin I and troponin T with Western blots. The troponin I fragment could be phosphorylated by cAMP-dependent protein kinase. In addition, we observed phosphorylation of a protein band that corresponded to myosin light chain-2 in myofibrils from CGI-treated hearts. These results suggest that degradation of thin-filament proteins may contribute to the changes in cooperativity of Ca2+ regulation of ATPase activity observed in the myofibrils from rat hearts exposed to CGI.
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PMID:Alterations in myofibrillar function and protein profiles after complete global ischemia in rat hearts. 153 Nov 86

We have previously demonstrated that withdrawal of insulin treatment from BB diabetic rats for a 24-hour period will increase the failure rate of hearts subjected to low-flow ischemia. The purpose of this study was to determine if this increased severity of ischemia was related to a decrease in glycolytic rates during ischemia. Two groups of insulin-dependent diabetic BB Wistar rats were used; in one group, insulin treatment was withheld from rats 24 hours prior to study (uncontrolled), while in the second group, the daily insulin injection was not withheld (insulin-treated). Isolated working hearts obtained from these animals were perfused with 30 mmol/L (2-3H/U-14C)-glucose and 1.2 mmol/L palmitate, at an 11.5 mm Hg left atrial preload and 80 mm Hg aortic afterload. Hearts were subjected to a 15-minute aerobic perfusion followed by 60 minutes of low-flow ischemia (coronary flow, 0.5 mL/min). Under aerobic conditions, steady-state glucose oxidation rates (measured as 14CO2 production) were decreased in the uncontrolled group compared with the insulin-treated group (85.3 +/- 21.5 v 406.2 +/- 120.1 nmol/min/g dry weight, respectively; P less than .05). Steady-state glycolytic rates (measured as 3H2O production) were also decreased in the uncontrolled group compared with the insulin-treated group (1.73 +/- 0.30 v 5.57 +/- 1.26 mumol/min/g dry weight, respectively; P less than .05). During low-flow ischemia, glucose-oxidation rates markedly decreased in both groups (23.9 +/- 8.7 and 38.3 +/- 25.2 nmol/min/g dry weight in the uncontrolled and insulin-treated diabetic rats, respectively).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Acute insulin withdrawal from diabetic BB rats decreases myocardial glycolysis during low-flow ischemia. 154 73

Low-pressure, hypothermic perfusion of isolated rabbit hearts for 24 hours compromises contractile function. This occurs despite continuous recirculation of an oxygenated solution. This investigation tested the hypothesis that such functional impairment results from irreversible tissue damage consequent to ischemia-induced lipid peroxidation. Decreases in coronary flow were measured during preservation and related to concentrations of thiobarbituric acid reactive species (TBA+, primarily malondialdehyde, a by-product of lipid peroxidation) in the tissue after preservation. The concentration of TBA+ species and the percent decrease in coronary flow rates at 30 minutes and 24 hours were positively correlated (r = 0.591 and r = 0.646, respectively). India ink was used as a marker of microvascular perfusion. Hearts showing the greatest magnitude of ischemia (evidenced by decreased percentages of perfused microvessels) had the highest levels of TBA+ species (r = 0.924). Moreover, hearts that had the highest levels of TBA+ species in the tissue exhibited the lowest levels of left ventricular function (as measured on a modified Langendorff apparatus; r = 0.767). We conclude that impaired coronary flow rates during perfused preservation portend compromised myocardial contractility. Furthermore, these changes occur largely within the first 30 minutes of perfusion. It is likely that early decrements in microvascular perfusion and consequent tissue injury owing to lipid peroxidation underlie impaired myocardial function after preservation.
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PMID:Lipid peroxidation results in compromised functional recovery of isolated rabbit hearts after low-pressure, hypothermic, perfused preservation for 24 hours. 154 52

The reduced thiol pool of myocardial tissue represents an important defense mechanism against oxygen toxicity. Since the ischemia-induced depletion of this pool might favor the cytotoxicity of oxygen-derived free radicals produced during reperfusion, we assessed the effects of the thiol group donor N-acetylcysteine in an isolated buffer-perfused rat heart model of ischemia/reperfusion. Fifty hearts were studied. A first series of experiments that consisted of two groups (n = 10) was designed to simulate the conditions of standard cardioplegic arrest. Hearts were subjected to 180 minutes of cold (15 degrees to 18 degrees C) global ischemia and 1 hour of reperfusion. The control group received crystalloid hyperkalemic cardioplegic solution given every 30 minutes during arrest, and the treated group received the same solution supplemented with N-acetylcysteine (0.04 mol/L). On the basis of comparisons of postreperfusion left ventricular developed pressure, maximal dP/dt, and diastolic pressure, N-acetylcysteine-containing cardioplegic solution afforded significantly better protection. A second series of experiments was then undertaken to assess the effects of N-acetylcysteine in hearts subjected to the sequence of ischemic events that is inherent in transplantation procedures. Hearts were cardioplegically arrested, stored for 5 hours at 2 degrees C, subjected to 1 additional hour of ischemic arrest at 15 degrees to 18 degrees C, and reperfused for 60 minutes. Three groups (n = 10) were studied that differed by the modalities of cardioplegic preservation used during the poststorage ischemic interval. One group received multidose unmodified cardioplegic solution. A second group received multidose cardioplegic solution supplemented with N-acetylcysteine (0.04 mol/L), and the third group was given only a single dose of N-acetylcysteine-enriched (0.07 mol/L) cardioplegic reperfusate at the end of arrest. Multidose N-acetylcysteine-containing cardioplegic solution resulted in a significantly better hemodynamic recovery than unmodified cardioplegic solution. The protection afforded by N-acetylcysteine was lost when the drug was given only at the time of reperfusion. We conclude that supplementation of cardioplegic solution with N-acetylcysteine markedly improves postarrest recovery of function, presumably through an enhancement of the reduced thiol pool, which increases the capacity of reperfused myocardium to handle the postischemic burst of free radical production. The clinical relevance of these findings stems from the fact that thiol-containing drugs are available for human use.
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PMID:Maintenance of the myocardial thiol pool by N-acetylcysteine. An effective means of improving cardioplegic protection. 156 75

Tumor necrosis factor (TNF)-alpha has significant biologic actions in many circumstances, such as infectious diseases, ischemia/reperfusion injury, and delayed-type hypersensitivity reactions. Based on the hypothesis that manipulation of TNF can play an important role in treatment of heart transplant rejection, the objective of this study was to determine whether anti-TNF antibodies could prolong cardiac allograft survival. Hearts from brown rats were transplanted to the necks of recipient Lewis rats. Graft survival was determined by direct palpation of the heart; complete graft rejection was defined by cessation of contraction. In untreated rats, the hearts were rejected 6.8 +/- 0.6 days (n = 10; mean +/- SEM) after transplantation. The mononuclear cell infiltrate in the transplanted hearts stained intensely for TNF by immunohistochemistry, indicating that TNF was present within the inflammatory cells associated with the rejection process. In rats receiving a single injection of anti-TNF antibody at the time of transplantation (n = 6), however, graft survival was nearly doubled (12.7 +/- 1.4 days; p less than 0.001 vs controls). Prolonged cardiac graft survival was also evident if the anti-TNF treatment was delayed until 1 day (n = 5; rejection at 16.2 +/- 2.4 days; p less than 0.001 vs controls) or even 3 days after transplantation (n = 5; rejection at 11.4 +/- 2.3 days; p less than 0.005 vs controls). Treatment at 5 days after transplantation, however, was not effective (n = 3; rejection at 7.7 +/- 0.6 days; p, not significant vs controls). The data indicate that a single bolus of anti-TNF antibodies can delay heart transplant rejection, even when administered up to 3 days after implantation, supporting the potential utility of anti-TNF therapy for treatment of heart transplant rejection.
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PMID:Antibodies against tumor necrosis factor prolong cardiac allograft survival in the rat. 157 39

The objective of this study was to determine the effect of adenosine on overall myocardial substrate utilization and mechanical function in isolated working rat hearts. Hearts were perfused with Krebs-Henseleit buffer containing 11 mM glucose (no fat) or with 11 mM glucose and 0.4 mM palmitate (normal fat). Steady-state rates of glycolysis, glucose oxidation, and fatty acid oxidation were measured by determination of quantitative 3H2O and 14CO2 production from radiolabeled substrates. The ratio of glycolysis (6.07 +/- 0.57 mumol.min-1.g dry wt-1) to glucose oxidation (3.12 +/- 0.28 mumol.min-1.g dry wt-1) under no fat conditions was 2:1. The addition of palmitate per se decreased glucose oxidation (to 0.81 +/- 0.09 mumol.min-1.g dry wt-1) and increased the glycolysis-to-glucose oxidation ratio to 6:1. Adenosine (100 microM) reduced this ratio to 3:1 by decreasing glycolysis (to 3.75 +/- 0.32 mumol.min-1.g dry wt-1) and increasing glucose oxidation (to 1.28 +/- 0.18 mumol.min-1.g dry wt-1) in the presence of palmitate. Steady-state palmitate oxidation rates were not altered by adenosine. Adenosine increased efficiency (work performed per unit O2 consumed) of spontaneously beating hearts but had no effect in paced hearts. These effects of adenosine on glucose metabolism may explain the beneficial actions of adenosine during reperfusion post ischemia.
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PMID:Adenosine modification of energy substrate use in isolated hearts perfused with fatty acids. 159 Apr 54

Exogenous fatty acids may promote arrhythmias during ischemia and reperfusion, perhaps by increasing myocardial concentrations of long-chain acylcarnitines. We therefore studied the effects of high concentrations of fatty acids on reperfusion arrhythmias and acylcarnitine accumulation in isolated working rat hearts subjected to regional ischemia and reperfusion. Hearts were perfused with buffer containing 3% albumin, 5.9 mM K+, and either 11 mM glucose or 11 mM glucose plus 1.2 mM palmitate. After 15 min of aerobic work, the left anterior descending artery was reversibly ligated for 10 min and released, and the hearts were subsequently reperfused for 3 min. Although ischemic zone acylcarnitine accumulation after reperfusion was significantly greater in glucose plus palmitate-perfused hearts (247 +/- 149 vs. 717 +/- 176 nmol/g dry wt in glucose- vs. palmitate-perfused hearts, respectively), no significant differences in the incidence (67 vs. 44%) or duration (95 +/- 17 vs. 56 +/- 17 s) of ventricular fibrillation (VF) were seen in glucose or glucose plus palmitate hearts, respectively. Because low K+ concentration ([K+]) has been reported to increase reperfusion arrhythmias in similar models, we reduced perfusate [K+] to 4.0 mM. This significantly increased the incidence and duration of VF in hearts perfused with glucose alone but had no effect in palmitate-perfused hearts. We conclude that acylcarnitine accumulation is not arrhythmogenic in this model and that fatty acids may actually have antiarrhythmic effects if exogenous [K+] is low.
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PMID:Effect of exogenous fatty acids on reperfusion arrhythmias in isolated working perfused hearts. 162 38

To determine the contribution of oxygen-derived free radicals to the changes in microvascular structure and function which follow reperfusion of ischemic myocardium, isolated perfused rat hearts were subjected to 15 or 45 min of global ischemia followed by 5 min of oxygenated reperfusion. Hearts were then fixed by perfusion with glutaraldehyde and perfused with nuclear track photographic emulsion to identify competent capillaries in scanning and transmission electron micrographs. Reperfusion after 15 min caused a significant reduction in the density of competent capillaries in the subendocardial third of the left ventricle, but this reduction was lessened but not eliminated by the addition of 0.61 mmole/liter desferrioxamine, but not by 60,000 U/liter superoxide dismutase plus 60,000 U/liter catalase, to the perfusate. After 45 min of ischemia both interventions prevented the myocyte swelling, endothelial cell changes, bleb formation, and reduction in microvascular lumina characteristic of unprotected reperfusion, but only desferrioxamine significantly improved microvascular competence. This suggests that the hydroxyl radical rather than superoxide and/or hydrogen peroxide has a pathogenic role, although desferrioxamine may have other effects as nonspecific chelator. Postischemic reductions in capillary function also occur in reversibly injured myocardium in the absence of structural abnormality. Preventing postischemic microvascular incompetence has the potential to minimize ischemic cell injury and to enhance repair following myocardial infarction, but it also may increase the risk of hemorrhage from venules.
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PMID:Anti-oxidant therapy improves microvascular ultrastructure and perfusion in postischemic myocardium. 163 71

An experimental animal model of hibernating myocardium is presented. Sixteen animals were initially prepared of which seven were selected for final review. Hearts were instrumented in two separate surgical procedures such that maximum phasic flow velocity in the left anterior descending (LAD) coronary artery was reduced by 50% and followed over 1 wk. Regional shortening declined at 1 wk to 62% of aerobic values (P less than 0.048) and did not improve over 2 h reperfusion. Metabolic determinations, obtained after 1 wk of coronary stenosis and immediately sampled before and after release of the LAD flow constrictor, showed no evidence of acidosis, hypercarbia, or an inability to extract oxygen at the tissue level. Thereafter, during the 2-h reperfusion period, hearts were able to respond to dobutamine (10 micrograms/kg infusion over 1 min) challenge with an appropriate shift in an end-systolic length estimate of contractility. Mitochondrial respiration at the conclusion of the studies in the reperfused bed demonstrated near normal recovery compared with aerobic values. None of the seven hearts showed gross evidence of infarction and only one heart was noted to have a few microfocal changes of healing infarction. Thus a new model of coronary stenosis is presented, which affected substantial reductions in mechanical function consistent with the concepts of hibernating myocardium. These mechanical events were not associated with marked metabolic abnormalities, reflecting advanced ischemia or mitochondrial dysfunction and could be transiently improved with inotropic stimuli. This model may prove beneficial as a tool in understanding mechanistic events underlying the hibernating heart.
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PMID:An animal model of chronic coronary stenosis resulting in hibernating myocardium. 163 59

We investigated in the isolated rat heart the influence of the gas surrounding the globally ischemic heart on transmural inhomogeneity of energy metabolism, extracellular K+ accumulation, and change of extracellular pH. Hearts were made ischemic in 100% N2 (N2-ischemia), 100% O2 (O2-ischemia) or 100% CO2 (CO2-ischemia). We measured: 1) Midmural, subepicardial, and epicardial changes of extracellular [K+] and pH during successive 6-min periods of global ischemia, and 2) content of creatinephosphate (CrP) in consecutive tissue sections of 100 microns, from the subepicardium after 10 min of ischemia. A) During O2-ischemia both extracellular [K+] and change of pH in the subepicardium are significantly less than in the midmyocardium. During N2-ischemia only minor differences exist in [K+] and pH between the subepicardium and the midmyocardium. During CO2-ischemia midmural and subepicardial [K+] are similar to those during N2-ischemia. The midmural change of pH resembles that during N2-ischemia; subepicardial change of pH, however, was slightly larger. Midmural changes in [K+] and pH were not influenced by the nature of the surrounding gas. B) After 10 min of O2-ischemia a gradient of tissue content of CrP extends from the epicardium (CrP about 30 mumoles/g dry weight) to a distance of about 1000 microns (CrP 1 mumoles/g dry weight). In N2- and CO2-ischemia a CrP gradient is absent; CrP is appreciably less than 1 mumoles/g dry weight at any distances from the epicardium. C) We conclude that diffusion of O2 into the myocardium and of CO2 from the myocardium affects transmural gradients of [K+], pH, and energy metabolism during ischemia. Local availability of O2 increases the capacity of the ischemic tissue to generate high energy phosphates and mitigates ischemia-induced changes of transsarcolemmal ion gradients.
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PMID:Transmural inhomogeneity of extracellular [K+] and pH and myocardial energy metabolism in the isolated rat heart during acute global ischemia; dependence on gaseous environment. 169 28


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