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

The subcellular distribution of ATP, ADP, creatine phosphate and creatine was studied in normoxic control, isoprenaline-stimulated and potassium-arrested guinea-pig hearts as well as during ischemia and after reperfusion. The mitochondrial creatine phosphate/creatine ratio was closely correlated to the oxidative activity of the hearts. This was interpreted as an indication of a close coupling of mitochondrial creatine kinase to oxidative phosphorylation. To further investigate the functional coupling of mitochondrial creatine kinase to oxidative phosphorylation, rat or guinea-pig heart mitochondria were isolated and the mass action ratio of creatine kinase determined at active or inhibited oxidative phosphorylation or in the presence of high phosphate, conditions which are known to change the functional state of the mitochondrial enzyme. At active oxidative phosphorylation the mass action ratio was one-third of the equilibrium value whereas at inhibited oxidative phosphorylation (N2, oligomycin, carboxyatractyloside) or in the presence of high phosphate, the mass action ratio reached equilibrium values. These findings show that oxidative phosphorylation is essential for the regulation of the functional state of mitochondrial creatine kinase. The functional coupling of the mitochondrial creatine kinase and oxidative phosphorylation indicated from the correlation of mitochondrial creatine phosphate/creatine ratios with the oxidative activity of the heart in situ as well as from the deviation of the mass action ratio of the mitochondrial enzyme from creatine kinase equilibrium at active oxidative phosphorylation in isolated mitochondria is in accordance with the proposed operation of a creatine shuttle in heart tissue.
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PMID:The role of the mitochondrial creatine kinase system for myocardial function during ischemia and reperfusion. 156 84

Isolated working rat hearts perfused with Krebs-Hensleit buffer were arrested and made ischemic. After 22 min, the hearts were reperfused with buffer, yielding restoration of function. Nucleotide levels rose and fell in the cardiac tissue as ischemia was imposed; the changes were consistent with the energy needs of the tissue. ATP concentrations in the tissues fell by 75% during ischemia, AMP levels were low initially and subsequently rose 5-fold, and ADP levels were essentially unchanged. Upon reperfusion ATP levels rebounded, although not to initial values, and AMP returned to initial values. During ischemia, there was a 10-fold or greater rise in inosine, hypoxanthine, and xanthine levels which fell to normally low levels upon reperfusion. Lactate dehydrogenase (LDH) activity rose during ischemia and returned to baseline upon reperfusion. Changes in LDH isozyme distribution suggest that, during ischemia, there is an increased proportion of liver-associated forms which returns to normally low levels upon reperfusion. Glutamate oxalacetate transaminase activity rose slightly at 5 min of ischemia, but, by 22 min of ischemia, it had fallen to 60% of initial values. Upon reperfusion, activity rose and, by 15 min, had reached 127% of initial values. On the other hand, there is no significant change in levels of extractable creatine kinase or isocitrate dehydrogenase activities as a result of the various conditions imposed on the hearts. As an index of protein oxidation, carbonyl levels in extractable protein rose during ischemia and were over four times the initial values at 5 min of reperfusion but, with continued reperfusion, declined to approximately 150% of initial values at 15 min.
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PMID:Biochemical effects of ischemia on isolated, perfused rat heart tissues. 157 15

In the conclusion of this series of reports, the application of 31P/2H NMR to investigate the pathophysiology of sepsis in rat hindlimb muscle is demonstrated. Sepsis decreased muscle [PCr] by 18%, 18 +/- 4 SD vs 22 +/- 4 SD mmol/kg tissue wet wt (P = 0.01) in control rats but [ATP] was unchanged, 6 mmol/kg tissue wet wt (P = 0.2). The derived free cytosolic [ADP] in the two groups was similar, [ADP]septic = 0.023 +/- 0.004 SD and [ADP]control = 0.021 +/- 0.003 SD mmol/kg tissue wet wt, and not statistically different (P = 0.14). Likewise [Pi] in the septic and control groups was not statistically different, [Pi]septic = 1.1 +/- 0.5 SD and [Pi]control = 1.2 +/- 0.4 SD mmol/kg tissue wet wt (P = 0.2). Septic rats presented the symptom of respiratory alkalosis evidenced by elevated blood pH. Sepsis decreased muscle blood flow by 33%, P = 0.003, but examination of individual subjects did not demonstrate a correlation with the reduction in [PCr]. Thus, a metabolic energy deficit caused by cellular ischemia/hypoxia is not a likely cause of cellular abnormality in rat hindlimb muscle during sepsis.
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PMID:Concurrent quantification of tissue metabolism and blood flow via 2H/31P NMR in vivo. III. Alterations of muscle blood flow and metabolism during sepsis. 159 58

Using NADH fluorometry to monitor myocardial metabolism, the mechanism of reperfusion injury was investigated after the delivery of an experimental reperfusate. Using an isolated working heart preparation, rat hearts underwent 15 min of global ischemia at 37 degrees C. Following the ischemic insult, an oxygenated enriched reperfusion solution was given for 5 min. The hearts were then returned to a working state and aortic flow recorded to evaluate recovery. NADH levels were monitored throughout the experiment with a fluorometer and glycogen, AMP, ADP, and ATP were measured biochemically pre- and postischemia, after reperfusion and after recovery. In this study, reperfusion injury was best abated by an enriched reperfusate. Our results indicate the mechanism for this amelioration is not high-energy phosphate replenishment. Rather, as indicated by NADH fluorescence, the hearts attain an intermediate level of metabolism that permits glycogen to be restored and functional recovery to be improved.
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PMID:Monitoring myocardial reperfusion injury with NADH fluorometry. 161 62

Preimplantation preparation of cardiac valves includes three major steps: (1) harvesting with accompanying ischemia (warm time from cessation of donor heart beat), (2) antibiotic disinfection, and (3) controlled-rate cryopreservation. To define the interdependent injury effects of these manipulations on leaflet matrix cells and specifically the potential for prolonged harvest-related ischemia to predispose greater injury by the subsequent steps, 96 semilunar valves were harvested from pigs in a manner analogous to human heart valve retrievals and randomly allocated to study groups as follows: 48 control valves were exposed to increasing harvested-related ischemic times, (2, 6, 12, 24 hr) and immersed in liquid nitrogen to arrest metabolic activity (i.e., prior to cryopreservation) and conclude the ischemia; another 48 were similarly harvested, subjected to identical ischemic times, then disinfected in 4 degrees C RPMI medium with standard antibiotics for 24 hr and dimethylsulfoxide cryopreserved at -1 degrees C/min to -170 degrees C (i.e., formal cryopreservation protocol). At thawing, each valve was extracted in 12% trichloroacetic acid and assayed by high performance liquid chromatography for components of the adenine nucleotide pool including ATP, lower energy nucleotides (total adenine nucleotides, [TAN] = [ATP] + [ADP] + [AMP]), adenosine, and the diffusible purines. Results are reported as nanomoles metabolite/milligram of leaflet cell protein (Lowry) and reflect a maintenance of total high energy phosphates in the control groups (5.41 +/- 0.29 nmole TAN at 2 hr; 8.34 +/- 0.67 nmole TAN at 24 hr), which fell significantly in all cryopreserved groups (1.27 +/- 0.33 nmole TAN at 2 hr; 0.34 +/- 0.22 nmole TAN at 24 hr).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:High energy phosphate depletion in leaflet matrix cells during processing of cryopreserved cardiac valves. 161 17

We administered fructose-1,6-bisphosphate (FDP), 1 mM, to isolated and perfused rabbit hearts submitted, after 90 minutes of equilibration, to an ischemic period (60 minutes at a coronary flow of 0.17 ml/min/g), followed by a period of reperfusion (30 minutes at a coronary flow of 3.6 ml/min/g). FDP was delivered at different times following the experimental protocol: 60 minutes before ischemia and for the entire experiment; 60 minutes before and during ischemia, but not at reperfusion; at the onset of ischemia and during reperfusion; and only during reperfusion. The FDP cardioprotective effect was evaluated in terms of recovery of left ventricular pressure developed during reperfusion, creatine phosphokinase (CPK) and noradrenaline release, mitochondrial function (expressed as yield, RCI, QO2, ADP/O), ATP and creatine phosphate (CP) tissue contents, calcium homeostasis, and by measuring oxidative stress in terms of reduced and oxidized glutathione release and tissue contents. Our data show that the cytoprotective action of FDP is closely related to the time of administration. Optimal myocardial preservation was achieved when it was present prior to ischemia and during reperfusion. When given at the time of ischemia or only on reperfusion, FDP does not exert cardioprotection. The data suggest that the FDP cardioprotective effect is related to improvement of energy metabolism.
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PMID:Role of timing of administration in the cardioprotective effect of fructose-1,6-bisphosphate. 163 29

The effect of normothermic ischemia and ischemia/reperfusion on the function of cardiac sarcoplasmic reticulum (CSR) was investigated using a modified Langendorff perfusion of isolated rat hearts. The function of the CSR was assessed by the oxalate-supported Ca2+ uptake rate of ventricular homogenates. The contribution of the ryanodine-sensitive portion of the CSR was determined by using 20 microM ruthenium red or 625 microM ryanodine to close the CSR Ca2+ release channel. The Ca2+ uptake rate of the CSR decreased progressively with increasing duration of ischemia, but this depression was much less when uptake was assayed in the presence of ryanodine. The depression in CSR Ca2+ uptake preceded ischemic contracture. Ryanodine and ruthenium red stimulated uptake almost equally in control hearts, but ruthenium red was much less effective than ryanodine after ischemia. This difference could not be overcome by increasing the ruthenium red concentration. These results confirm the suggestion that the Ca2+ release channel is inappropriately opened after ischemia. The CSR uptake rates were almost completely restored at 15 minutes of reperfusion after 5 and 10 minutes of ischemia but were only partially restored after 15 minutes of ischemia. At reperfusion, mechanical function (end-diastolic pressure and peak systolic developed pressure) was markedly depressed after only 15 minutes of ischemia. The degree of "stunning" correlated well with the depression of CSR function in individual hearts. The decreased Ca2+ uptake of the CSR was not due to a buildup of ADP in the homogenates.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Reversibility of the effects of normothermic global ischemia on the ryanodine-sensitive and ryanodine-insensitive calcium uptake of cardiac sarcoplasmic reticulum. 172 84

This study assessed gentamicin's effects on ischemia/reperfusion renal injury to better understand when and how it worsens postischemic acute renal failure. Rats were subjected to 25 minutes of renal pedicle occlusion with and without preischemic (15-minute) or postischemic (15-minute or 8-hour) gentamicin treatment (100 mg/kg, by itself a subtoxic dose). Gentamicin's impact on hypoxia/reoxygenation injury to isolated rat proximal tubular segments was also assessed. Preischemic and postischemic gentamicin worsened the severity of acute renal failure to the same degree, suggesting that pretreatment induces its effect in the reperfusion period. Gentamicin paradoxically lessened hypoxic damage to proximal tubular segments (assessed by lactate dehydrogenase release), again implying no adverse impact on oxygen deprivation-induced tubular injury. From 0-4 hours of reperfusion, gentamicin approximately halved ATP/ADP ratios (due to increased ADP), indicating a drug-induced defect in cellular energetics. This abnormality temporally correlated with evolving morphological damage. Although antioxidants (deferoxamine and sodium benzoate) have been reported to protect against pure aminoglycoside nephrotoxicity, they did not mitigate gentamicin's adverse impact on postischemic acute renal failure. Gentamicin did not influence ischemia/immediate reperfusion deacylation/reacylation (assessed by renal free fatty acid content) despite its known antiphospholipase activity. Although in the normal kidney gentamicin preferentially accumulated in cortex, in the postischemic kidney, both cortex and outer medullary stripe developed striking (approximately threefold to fivefold) and comparable gentamicin increments. In conclusion, gentamicin appears to exacerbate postischemic acute renal failure by adversely influencing the reperfusion, not the ischemic injury, process. This may occur because increased gentamicin accumulation negatively impacts on reperfusion cellular energetics.
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PMID:Gentamicin effects on renal ischemia/reperfusion injury. 172 86

Myocardial ATP, ADP, and AMP were measured from cardiac biopsy in 11 dogs after intracoronary injection of 6 mL of sodium-meglumine diatrizoate (SMD), iohexol (IOH), or 0.9% sodium chloride (NaCl), and in three of the dogs at baseline before any injection. The ATP at baseline and after SMD, IOH, and 0.9% NaCl were 5.39 +/- 0.41, 3.72 +/- 0.70, 5.52 +/- 0.82, and 5.44 +/- 1.40 mumol/g wet weight, respectively. There were significant differences between SMD and IOH (P less than .02), and between SMD and 0.9% NaCl (P less than .05). The energy charge of SMD was 0.82 +/- 0.08, which differed from 0.89 +/- 0.02 for NaCl or 0.9 +/- 0.05 for baseline (P less than .05), but not from 0.85 +/- 0.04 for IOH. In conclusion, diatrizoate caused significant depletions in ATP stores in comparison with iohexol, but there was no significant difference with respect to energy charge. Nonionic contrast media would be preferable for coronary arteriography in patients whose high-energy stores might be depleted from severe ischemia.
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PMID:Effects of intracoronary administration of contrast media on myocardial high-energy phosphate. A comparison of sodium meglumine diatrizoate and iohexol. 173 78

The quantification of adenine nucleotides released from the heart is hampered by their rapid dephosphorylation to adenosine in the extracellular space catalyzed by highly active ectonucleotidases. To determine the total release of adenine nucleotides from isolated Langendorff-perfused guinea pig hearts, ecto 5'-nucleotidase was effectively blocked by infusion of alpha, beta-methylene-ADP (AOPCP, 50 microM). Adenine nucleotides were measured in the coronary venous effluent by the luciferin-luciferase method after enzymatic rephosphorylation to ATP. In hearts perfused at a constant flow rate (10 ml/min) with normoxic buffer (95% O2, 5% CO2) the release +/- SEM of adenine nucleotides and adenosine was 0.06 +/- 0.01 (n = 11) and 0.04 +/- 0.01 (n = 13) nmol/min. In the presence of AOPCP, the release of adenine nucleotides increased to 0.43 +/- 0.04 nmol/min (n = 9; p less than 0.05), whereas adenosine remained unchanged. Hypoxic perfusion (10% O2, 85% N2, 5% CO2) caused a threefold increase in adenine nucleotide release but a 40-fold increase in adenosine. In contrast, global ischemia (30 seconds) caused adenine nucleotide and adenosine release to rise to similar values of 1.06 +/- 0.10 and 0.80 +/- 0.14 nmol/min (n = 9). Stimulation of hearts with isoproterenol (4 nM) likewise increased the release of adenine nucleotides (0.50 +/- 0.04 nmol/min) and adenosine (0.87 +/- 0.21 nmol/min) (n = 6). To determine the cellular source of adenine nucleotides released from the heart, the coronary endothelial adenine nucleotide pool was selectively prelabeled by [3H]adenosine. Global ischemia increased the specific radioactivity of released adenine nucleotides by 57%. The findings indicate that 1) adenine nucleotides and adenosine are released at the same order of magnitude from the well-oxygenated heart; 2) beta-adrenergic stimulation and ischemia stimulate the release of adenine nucleotides and adenosine, both purines reaching vasoactive concentrations in the effluent perfusate; 3) during hypoxic perfusion only the release of adenosine is greatly enhanced; and 4) the coronary endothelium preferentially contributes to the ischemia-induced adenine nucleotide release.
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PMID:Adenine nucleotide release from isolated perfused guinea pig hearts and extracellular formation of adenosine. 174 67


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