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

The isolated perfused working rat heart preparation has been used to study the effects of respiratory acidosis on myocardial metabolism and contractilly. Hearts were perfused with 5 mM glucose and 10(-2) U/ml of insulin in order to enhance metabolsim of glucose relative to that of fatty acids. After perfusion with Krebs bicarbonate medium at pH 6.6, hearts rapidly ceased performing external work and peak left ventricular pressure fell by 75% after 5 minutes. Oxygen consumption, rate of ATP generation and overall glycolytic flux also declined rapidly. After about 2 minutes of perfusion, the fall of glycolytic flux showed a partial reversal, which was largely accounted for by increased lactate production, so that glucose oxidation decreased further. The reversal of glycoltic flux could be accounted for by partial release of H+ inhibition of phospho-fructokinase by increased tissue levels of adenosine 5'-diphosphate (ADP), adenosine monophosphate (AMP) and P1 and decreased levels of adenosine triphosphate (ATP) and creatine phosphate. The increased proportion of glucose uptake converted to lactate together with an increase of the tissue lactate/pyruvate ratio could be accounted for by inhibition of the malate-aspartate cycle combined with tissue hypoxia. Lactate accumulated in the tissue as a result of a decreased permeability of the plasma membrane to lactate. Decreased oxygen delivery to the myocardium was caused by secondary constriction of the coronary vessels. In further experiments, the coronary flow was regulated by an external pump which delivered fluid at a controlled rate into the aortic cannula above the coronary arteries, and the degree of tissue hypoxia was monitored by measuring changes of pyridine nucleotide reduction state by surface fluorescence techniques. The effects of acidosis uncomplicated by possible hypoxia were compared directly with those produced by ischemic hypoxia. The effects of acidosis under these conditions were similar to those described above, and to those produced by ischemia. From these and other data it is concluded that the effects of ischemia are caused by a lowering of the intracellular pH, which decreases the rate of energy production relative to the rate of energy demand. However, it is suggested that the primary cause of the decreased peak systolic pressure with either acidosis or ischemia is not a result of a defect of energy metabolism, but is due to alteration of the calcium cycle of the heart. Possible causes of irreversible heart failure after prolonged ischemia are discussed.
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PMID:Contribution of tissue acidosis to ischemic injury in the perfused rat heart. 0 93

The relationship of changes in regional coronary flow to the nature and degree of biochemical disturbances during occlusion of branches of the left anterior descending coronary artery and following reestablishment of flow was investigated in two groups of dogs: group I, moderate ischemia before reflow, and group II, severe ischemia prior to reflow. Regional coronary blood flow was determined before ligation, after 60 min of ischemia and after 15 min of reflow using labelled microspheres. Hearts made ischemic for 60 min but not reperfused served as controls. Groups I and II were distinguished by the following features. Group II showed a marked exacerbation of biochemical damage on reperfusion of the ischemic region (reduced levels of ATP, impairment of mitochondrial oxygen consumption and mitochondrial calcium binding). This was accompanied by significant subendocaridial hyperemia. Reperfusion in group I, on the otherhand, partially reversed these changes (increased level of ATP in the ischemic-reperfused region, improved mitochondrial oxygen consumption and calcium binding). Mitochondrial calcium uptake and oxidative phosphorylation (ADP/O ratio) were not affected in any group. These data illustrate that the degree of biochemical damage following reperfusion of the ischemic myocardium is determined by the degree of ischemia, and suggest that interference with ATP production by the mitochondria is not responsible for the damage.
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PMID:The relationship of regional coronary blood flow to mitochondrial function during reperfusion of the ischemic myocardium. 50 23

Cold blood with potassium, 34 mEq/L, was compared with cold blood and with a cardioplegic solution. Three groups of 6 dogs had 2 hours of aortic cross-clamp while on total bypass at 28 degrees C with the left ventricle vented. An initial 5-minute coronary perfusion was followed by 2 minutes of perfusion every 15 minutes for the cardioplegic solution (8 degrees C) and every 30 minutes for 3 minutes with cold blood or cold blood with potassium (8 degrees C). Hearts receiving cold blood or cold blood with potassium had topical cardiac hypothermia with crushed ice. Peak systolic pressure, rate of rise of left ventricular pressure, maximum velocity of the contractile element, pressure volume curves, coronary flow, coronary flow distribution, and myocardial uptake of oxygen, lactate, and pyruvate were measured prior to ischemia and 30 minutes after restoration of coronary flow. Myocardial creatine phosphate (CP), adenosine triphosphate (ATP), and adenosine diphosphate (ADP) were determined at the end of ischemia and after recovery. Changes in coronary flow, coronary flow distribution, and myocardial uptake of oxygen and pyruvate were not significant. Peak systolic pressure and lactate uptake declined significantly for hearts perfused with cold blood but not those with cold blood with potassium. ATP and ADP were lowest in hearts perfused with cardioplegic solution, and CP and ATP did not return to control in any group. Heart water increased with the use of cold blood and cardioplegic solution. Myocardial protection with cold blood with potassium and topical hypothermia has some advantages over cold blood and cardioplegic solution.
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PMID:Cold blood as the vehicle for potassium cardioplegia. 51 80

During reperfusion, functional and metabolic recovery of the isolated working rat heart from one hour of ischemia was best in hearts selectively cooled at the onset of the ischemic interval by perfusion with 5 to 10 ml. of 10 degrees C. or 15 degrees C. Krebs-Henseleit buffer. Hearts similarly perfused at 4 degrees C., 20 degrees C. recovered significantly less well or not at all. Immediately after the hour of ischemia and prior to reperfusion, the absolute levels of glycogen and high-energy phosphates were best in the hearts perfused at 4 degrees C. However, metabolic function was best preserved in those perfused at 10 degrees C. and 15 degrees C., as evidenced by rapid recovery of high-energy phosphates and glycogen to control levels compared to metabolic deterioration in the 4 degrees C. group.
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PMID:Effect of perfusate temperature on myocardial protection from ischemia. 85 Apr 37

Whole-heart ischemia has been induced in isolated working rat heart. The distribution of the reduced coronary flow was even, as judged by 3H-antipyrine autoradiographs. Reducing the coronary flow resulted in myocardial ischemia, as indicated by a lowered tissue content of glycogen, ATP and creatine phosphate and accumulation of lactate. After a reperfusion period of 30 min there was a restoration of glycogen, ATP and creatine phosphate for hearts that were ischemic for 5 and 10 min, with a concomitant normalization of tissue lactate. Hearts that were ischemic for 30 min did not show restoration of high energy phosphates and glycogen. There was a leakage of ASAT, CK and LD in all groups of hearts, suggesting that a release of these enzymes does not necessarily indicate an irreversibly damaged myocardial cell.
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PMID:Significance of enzyme release from ischemic isolated rat heart. 87 8

A new experimental model for the study of two important aspects of ischemia, namely, oxygen and substrate deprivation, is proposed: the intact, beating fetal mouse heart in organ culture. This model offers long-term stability, ease and reproducibility of preparation, and the ability to manipulate experimental conditions. Hearts deprived of oxygen and glucose ceased beating immediately. After 3-4 hr of deprivation, biochemical and ultrastructural changes consistent with ischemic injury were evident. These include depletion of ATP and glycogen levels, loss of cytoplasmic enzymes, and extensive swelling and disruption of mitochondrial structure. Glucose and insulin partially protected against ATP depletion. Upon resupply of oxygen and glucose , beating resumed immediately, ATP levels rapidly increased to control levels and, consistent with this, mitochondrial structure returned toward normal. During the recovery phase autophagic vacuoles containing damaged mitochondria and myofibrils were seen, indicating that repair mechanisms were activated. Consistent with this, the proportion of lysosomal enzymes that were present in the nonsedimentable fraction of the tissue homogenate increased. We conclude that the cultured fetal mouse heart is a model useful for studying myocardial responses to anoxia and/or substrate deprivation and for assessing interventions designed to limit damage or to stimulate repair after ischemic injury.
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PMID:Fetal mouse hearts: a model for studying ischemia. 105 96

The effect of 40- or 90-min periods of temporary myocarardial ischemia on the distribution of coronary flow and capillary structure were assessed in groups of mongrel dogs. Thioflavin S. a fluorescent dye which stains vascular endothelium when injected intravenously, was used to demonstrate the distribution of microvascular perfusion at 10 sec, 5 min, or 20 min following release of a 40-or 90min circumflex coronary artery occlusion. Hearts which demonstrated perfusion defects were sampled for electron microscopy. Following 40 min of occlusion, thioflavin S was distributed uniformly throughout the myocardium. In contrast, following 90-min periods of coronary occlusion, perfusion defects always were present in the subendocardial half of the posterolateral left ventricular wall. Several morphological features in these areas of no reflow were observed by electron microscopy, including decreased endothelial pinocytotic vesicles, endothelial gaps and bleb formation, capillaries packed with erythrocytes, occasional intraluminal thrombi, and extravascular erythrocytes and fibrin. Myocardial cells showing severe injury always were seen within but also extended beyond the areas of poor perfusion. These results demonstrate that areas of no reflow occur following 90-min periods of ischemic injury in the dog, but that primary myocardial cell injury occurs during the ischemic period and not as a function of the "no-reflow" phenomenon.
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PMID:Demonstration of the "no-reflow" phenomenon in the dog heart after temporary ischemia. 120 94

This study was designed to evaluate the relative response of myocardial efficiency to reduced oxygen supply (hypoxia and ischemia) in immature and mature isolated rabbit hearts. Hearts were subjected to either 15 min of hypoxia (60% or 30% O2) or reductions in coronary flow to 75%, 50%, 25%, and 15% of basal flow followed by 12 min of total global ischemia and 15 min of reperfusion. In order to examine changes in cardiac efficiency, we utilized the ratio of isovolumic contractile function (rate-pressure product) to myocardial oxygen consumption (RPP/MVO2). Under basal conditions, immature hearts displayed lower aortic pressure. RPP, coronary resistance and RPP/MVO2. Moderate hypoxia (60% O2) resulted in similar reductions in RPP and MVO2 in both age groups, with RPP/MVO2 remaining unchanged. During severe hypoxia, RPP/MVO2 increased significantly in mature hearts but not in immature hearts (P < 0.05). Underperfusion produced greater reductions in RPP and heart rate, whereas reperfusion after ischemia resulted in greater recovery of RPP, dP/dt and MVO2 in immature compared to mature hearts. When oxygen supply was limited by reductions in coronary perfusion. RPP/MVO2 tended to increase in mature hearts, whereas the ratio declined significantly in immature hearts. These data demonstrate that, in this model, a reduction in oxygen supply by hypoxia or hypoperfusion decreases efficiency in immature hearts, but increases efficiency in mature hearts under the same conditions.
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PMID:Changes in work rate to oxygen consumption ratio during hypoxia and ischemia in immature and mature rabbit hearts. 129 15

Hearts with compensatory pressure-overload hypertrophy show an increased intracardiac activation of angiotensin II that may contribute to ischemic diastolic dysfunction. We studied whether pressure-overload hypertrophy in response to aortic banding would result in exaggerated diastolic dysfunction during low-flow ischemia and whether the specific inhibition of the cardiac angiotensin converting enzyme by enalaprilat would modify systolic and diastolic function during ischemia and reperfusion in either hypertrophied or nonhypertrophied hearts. Isolated, red blood cell-perfused isovolumic nonhypertrophied and hypertrophied rat hearts were subjected to enalaprilat (2.5 x 10(-7) M final concentration) infusion during 20 minutes of baseline perfusion and during 30 minutes of low-flow ischemia and 30 minutes of reperfusion. Coronary flow per gram was similar in nonhypertrophied and hypertrophied hearts during baseline perfusion, ischemia, and reperfusion. At baseline, left ventricular developed pressure was higher in hypertrophied than nonhypertrophied hearts in untreated groups (224 +/- 8 versus 150 +/- 9 mm Hg; p less than 0.01) and in enalaprilat-treated groups (223 +/- 9 versus 145 +/- 8 mm Hg; p less than 0.01). During low-flow ischemia, left ventricular developed pressure was depressed but similar in all groups. All groups showed deterioration of diastolic function; however, left ventricular end-diastolic pressure increased to a significantly higher level in untreated hypertrophied than in nonhypertrophied hearts (65 +/- 7 versus 33 +/- 3 mm Hg; p less than 0.001). Enalaprilat had no effect in nonhypertrophied hearts, but it significantly attenuated the greater increase in left ventricular end-diastolic pressure in hypertrophied hearts treated with enalaprilat compared with no drug (65 +/- 7 versus 50 +/- 5 mm Hg; p less than 0.01). The beneficial effect could not be explained by differences in coronary blood flow per gram left ventricular weight, glycolytic flux as reported by lactate production, myocardial water content, oxygen consumption, and tissue levels of glycogen and high energy phosphate compounds. During reperfusion, all hearts showed a partial recovery of developed pressure to 70-74% of initial values. No effect of enalaprilat could be detected during reperfusion on systolic and diastolic function or restoration of tissue levels of high energy compounds. In conclusion, our experiments show that hypertrophied red blood cell-perfused hearts manifest a severe impairment of left ventricular diastolic relaxation in response to low-flow ischemia in comparison with control hearts. Further, our experiments support the hypothesis that the enhanced conversion of angiotensin I to angiotensin II in rats with pressure-overload hypertrophy contributes to the enhanced sensitivity of hypertrophied hearts to diastolic dysfunction during low-flow ischemia.
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PMID:Exacerbation of left ventricular ischemic diastolic dysfunction by pressure-overload hypertrophy. Modification by specific inhibition of cardiac angiotensin converting enzyme. 131 16

Rapid washout of extracellular H+ accumulated during preceding ischemia (i.e., the abrupt restoration of extracellular pH) has been implicated as an arrhythmogenic factor during reperfusion. Therefore, we hypothesized that by limiting the rate at which extracellular pH was restored during early reperfusion it should be possible to protect against reperfusion-induced arrhythmias. To test this, we used isolated rat hearts (n = 12 per group) and a novel dual coronary perfusion cannula that permitted the induction of regional ischemia (10 minutes) and the selective reperfusion (8 minutes) of the ischemic zone with modified solutions. We examined the antiarrhythmic efficacy of 1) acidic (pH 6.6) reperfusion with stepwise restoration of extracellular pH to 7.4 (stepped pH) and 2) transient (2-minute) acidic (pH 7.1, 6.8, 6.6, or 6.4) reperfusion with subsequent abrupt restoration of extracellular pH to 7.4. Hearts in two contemporary control groups were reperfused with solution at pH 7.4 throughout. In all groups, 100% of hearts exhibited ventricular tachycardia (VT) on reperfusion. VT degenerated into ventricular fibrillation (VF) in 100% of hearts in the control group but in only 42% of hearts in the stepped-pH group (p < 0.05). In the groups subjected to transient acidic reperfusion, there was a pH-dependent prolongation of VT cycle length (measured at 15 seconds of reperfusion), which was 47.1 +/- 3.9, 51.1 +/- 5.5, 56.0 +/- 1.9, 60.4 +/- 2.8 (p < 0.05), and 68.8 +/- 5.0 (p < 0.05) msec in the pH 7.4 (control), 7.1, 6.8, 6.6, and 6.4 groups, respectively. In these groups, VT degenerated into VF in 92%, 92%, 83%, 42% (p < 0.05), and 33% (p < 0.05) of hearts, respectively. In conclusion, limiting the rate at which extracellular pH is restored during early reperfusion does not affect the rapid induction of VT but inhibits the degeneration of VT into VF and promotes spontaneous reversion to normal sinus rhythm. This is consistent with a major arrhythmogenic role, during uncontrolled reperfusion, for the rapid washout of extracellular H+.
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PMID:Reperfusion-induced arrhythmias. A role for washout of extracellular protons? 133 Mar 56


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