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)

Brief periods of ischemia have been shown to produce marked reactive hyperemia in both red (slow) and white (fast) skeletal muscle. However, evidence is lacking for specific vasodilator metabolites which are rapidly produced in ischemic skeletal muscle. The present study examined the effects of 1 and 3 minutes of ischemia on creatine phosphate (CrP), adenine nucleotide metabolism, and anaerobic glycolysis in red anterior (ALD) and white posterior latissimus dorsi (PLD) muscles of the chicken. Tissue metabolite concentrations were determined from perchloric acid or trichloroacetic acid extracts using enzymatic assay or high pressure liquid chromatography. CrP or adenine nucleotides were not significantly altered in either muscle following 1 or 3 minutes of ischemia. However, adenosine increased by 611% in the ALD at 1 minute. Following 3 minutes of ischemia, adenosine concentrations were elevated by 439% and 201% in the ALD and PLD, respectively. The PLD showed the greatest increases in inosine and IMP. Inorganic phosphate increased by 67% and lactate increased by 142% in the ALD at 3 minutes. The PLD, which is reported to have a high anaerobic glycolytic capacity, showed no increase in lactate. These results support the hypothesis that adenosine may be a mediator of akeletal muscle reactive hyperemia following short periods of ischemia.
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PMID:Effects of ischemia on tissue metabolites in red (slow) and white (fast) skeletal muscle of the chicken. 45 3

The isolated perfused rat heart was utilized to determine the maximum rate of adenosine incorporation into adenine nucleotides and the effect of ischemia on this rate. In aerobic hearts, the rates of [8-14C]adenosine incorporation into nucleotides in nanomoles/minute per gram dry tissue were ATP 34 +/- 2, ADP 6 +/- 0.4, AMP 3 +/- 0.3, and IMP, 1 +/- 0.2. Following ischemia these values were not significantly different except for the rate of incorporation into IMP, which doubled. The extent of adenosine deamination with one pass through the coronary vasculature was the same in aerobic and postischemic hearts: 2% and 7% of the perfusate adenosine was converted to hypoxanthine and inosine, respectively. These percentages were similar at 50, 100, and 200 micron adenosine. Perfusion of aerobic hearts for 5 h with adenosine did not change ATP concentrations. Therefore, [8-14C]adenosine incorporation into ATP in these hearts appeared to represent ATP turnover. In contrast, 5 h perfusion of postischemic hearts with adenosine restored ATP concentrations to control values. The synthesis rate calculated from the increase in ATP concentration was comparable to the synthesis rate calculated from [8-14C]adenosine incorporation. Thus, incorporation of [8-14C]adenosine into ATP in postischemic hearts represented net ATP synthesis.
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PMID:Myocardial adenosine salvage rates and restoration of ATP content following ischemia. 46 18

Cultured chick heart muscle cells degrade ATP during metabolic inhibition via ADP to AMP. Whether AMP is primarily deaminated to IMP or dephosphorylated to adenosine depends on the 'metabolic block' (glycolysis vs. oxidative phosphorylation). Inhibition of glycolysis (deoxyglucose) results in an inosine/adenosine ratio greater than 1 in the supernatant, whereas the nucleoside ratio is less than or equal to 1 during inhibition of oxidative phosphorylation (hypoxia, rotenone). EHNA, a blocker of adenosine deaminase, has little effect on inosine release during metabolic inhibition, consistent with the reported low activity of adenosine deaminase in cardiac muscle cells. The amount of adenosine and inosine released can be largely attenuated by two nucleoside carrier inhibitors, nitrobenzyl-thioinosine and dipyridamole, which suggests that nucleosides are produced intracellularly and subsequently released. These results indicate that the amount of inosine or adenosine released from the cardiomyocyte during impaired energy metabolism (e.g. ischemia) can be controlled by the metabolic state of the cell.
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PMID:Adenine nucleotide degradation in cultured chick heart muscle cells. 179 25

The effect of lidocaine on the ischemic nor-mothermic rat heart was studied in a Langendorff preparation. Ventricular fibrillation, total retrograde coronary flow and effluent lactate concentration were monitored in preischemia (control), ischemia (20 min) and reperfusion (20 min). Myocardial metabolites were determined in specimens excised at termination of reperfusion. Six hearts were infused with lidocaine in Ringer solution at onset of ischemia (group A) and six with only Ringer solution (group B). Sinus rhythm proceeded directly to diastolic arrest after 17 sec in group A, while all group B hearts showed ventricular fibrillation before arrest at 174 sec. Effluent lactate concentration was reduced in group A during the first 10 min of ischemia, but not subsequently. After 10 min of reperfusion, coronary flow was reduced by 12% in group A and 20% in group B. ATP was higher and ADP, AMP and IMP were lower in group A than in group B after 20 min of reperfusion. Creatine phosphate showed no intergroup difference, but creatine was higher in group B. Cardiac arrest with lidocaine thus reduced lactate formation during ischemia and lessened high-energy phosphate depletion after reperfusion.
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PMID:The effect of lidocaine on myocardial ischemia with asanguinous reperfusion. An in vitro study. 194 8

Cultured heart cells have been recently shown to be useful for analysing states of oxygen- and volume-restrictions, conditions that are known to simulate anoxia and ischemia at the cellular level. In the present study, we examined the ultrastructural damage caused to cultured neonatal rat heart cells when they were subjected to simulated ischemia by volume restricted anoxia ('ischemia') in an in vitro system. Both thin-sectioning and freeze-fracturing electron microscopy revealed a mitochondrial reorganization after 30 min of 'ischemia', whereas multilamellar structures could be detected inside the mitochondria after another 30 min. At this time-point, changes were also observed regarding the organization of the sarcolemma. In addition to a slight aggregation of the intramembranous particles (IMP's) we found an extensive extrusion of particle-free multilamellar membrane-structures, possibly due to a loss of the sarcolemma/cytoskeleton-interaction. These morphological changes are comparable to those previously observed in in vivo and Langendorff studies and the results of the present study therefore underline the usefulness of this recently introduced model for ischemia.
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PMID:The isolated neonatal rat-cardiomyocyte used in an in vitro model for 'ischemia'. I. A morphological study. 200 10

Using Langendorff rat hearts, we tested whether 1. adenosine as a cardioplegic agent, and 2. inosine administered during reperfusion could prevent and treat ischemic injury, respectively. For cardioplegic arrest (37 degrees C), buffer supplemented with 20 mM K+ (K), K + 1 mM adenosine (KA), or none (Control, C), was infused for 3 min at 3 ml/min. Arrest time was 260 +/- 16 s (C), 22 +/- 4 s (K) and 10 +/- 2 s (KA, p less than 0.02 vs K). During 20 min total ischemia, resting tension increased only in C, and remained elevated after 20 min reperfusion. In treated hearts resting tension rose somewhat and returned to baseline. Developed tension: heart rate (g/min) after reperfusion was superior with KA:C (3,180 +/- 830), K (4,380 +/- 390), and KA (6,250 +/- 740, p less than 0.05 vs. K.). Our electrophysiological studies suggest that adenosine increases K(+)-permeability and thereby arrests the sinus node. It did not affect high-energy phosphates. We also tested whether inosine could regenerate nucleotides. We perfused hearts with buffer containing glucose +/- pyruvate. After 15 min no-flow, hearts were reperfused for 45 min with 20 microM inosine and 0.5 mM ribose. Adenine nucleotide levels tended to recover better in the purine-treated groups. Inosine decrease the ATP/ADT ratio by 15% (p less than 0.05) and increased the IMP level 2 times (p less than 0.01) whom pyruvate was absent. It increased the effluent adenosine concentration 6 times (p less than 0.005). Inosine administration +/- pyruvate did not affect function recovery, heart rate or coronary flow. Thus adenosine as adjunct to K(+)-cardioplegia shortened arrest time, and was also beneficial for post-ischemic recovery. Inosine given during reperfusion failed to improve heart function. Both treatments hardly affected cardiac adenine nucleotide levels.
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PMID:Prevention and treatment of ischemic injury with nucleosides. 202 58

Reports on enhanced nucleotide regeneration by purines during reperfusion are conflicting. We have, therefore, evaluated the effects of inosine or adenine, administered after ischemia, on adenine nucleotide levels and function in isolated rat hearts. The hearts were perfused with a Tyrode solution, containing 10 mM D-glucose, with or without 5 mM pyruvate. After 15 minutes without flow, the hearts were reperfused for 45 minutes with 20 microM purine and 0.5 mM D-ribose. Adenine nucleotide levels tended to recover better in the purine-treated groups. The purines decreased the ATP/ADP ratio by 10-15% (p less than 0.05) if pyruvate was absent. The IMP level in the inosine/glucose group exceeded that in all other groups by a factor of two (p less than 0.001). Inosine increased the adenosine concentration in the effluent sixfold (p less than 0.005). The hypoxanthine concentration rose up to four times following adenine treatment (p less than 0.05). The administration of purine, with or without pyruvate, did not affect mechanical recovery, heart rate or coronary flow. We conclude that inosine and adenine failed to improve cardiac function and hardly affected nucleotide levels in the reperfused heart.
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PMID:Effects of inosine and adenine on nucleotide levels in the post-ischemic rat heart, perfused with and without pyruvate. 210 91

The recovery of both contractile performance and metabolic response of rat heart following 1 h of ischemia after equilibration with glucose + insulin (glucose-ischemia) or with pyruvate (pyruvate-ischemia), was tested in normoxic reperfusion in the presence of glucose + insulin, pyruvate, lactate or acetate. In glucose-ischemia only the reperfusion with pyruvate results in a complete recovery of the contractile force (left ventricular pressure, LVP) (170%) and good recovery of high energy phosphate compounds. Lower LVP and tissue energy charge were found in glucose reperfusion and even less in lactate and acetate reperfusion. Disappearance of the IMP accumulated during ischemia is evident only in the pyruvate reperfusion indicating a higher metabolic recovery. On the contrary in pyruvate-ischemia all types of reperfusion tested were effective in reactivating the contractile force (although acetate to a lesser extent); the contractile activity was accompanied by a good recovery of phosphocreatine, ATP, energy charge and by the decrease of IMP. Large decreases of adenine nucleotides and NADP and lower decreases of NAD are observed during ischemia/reperfusion in both systems. Pyruvate-ischemia is quite similar to, if not worse than glucose-ischemia, for all the metabolic parameters considered, but not worse for the possibility of recovery. Some specific effect of pyruvate should be exerted during the ischemic phase. The mechanism of pyruvate protection is discussed in relationship to: (i) the possible activation of pyruvate dehydrogenase, (ii) the activation of NADPH-dependent peroxide scavenging systems, (iii) the direct scavenging action of pyruvate on H2O2.
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PMID:The protective action of pyruvate on recovery of ischemic rat heart: comparison with other oxidizable substrates. 218 87

Three cases of chronic subdural hematoma (CSDH) revealed by transient neurological accidents are reported. Although well-known this condition is rare: 1 to 9 p. 100 of CSDHs. Questioning may bring out a history of cranial injury and headache, even minor ones, which are unusual in transient ischemic accidents (TIA). Transient phenomena, such as motor aphasia or speech interruption, point to the diagnosis, especially in male patients over 60 years of age. The finding at electroencephalography of a delta activity more than 48 hours after a TND should exclude the diagnosis of TIA until a CT scan is performed. Since the causes of neurological deficits regressing within less than 24 hours may be ischemia as well a hemorrhage or tumour, the term of transient neurological accident (TNA) should preferably be used, and an emergency CT scan should be performed for diagnostic and therapeutic purposes. Owing to the possibility of another concomitant cause of TNA, the finding of a subdural haematoma should not deter from pursuing cardiovascular examinations. The mechanism of TNA probably involves a vascular factor, as suggested by I-123 IMP cerebral SPECT which shows an intercritical decrease in cerebral blood flow and/or an epileptic factor.
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PMID:[Chronic subdural hematoma and transient neurologic deficits]. 219 36

An in vivo rat hindlimb tourniquet ischemia model was used to study the purine nucleotide metabolism in response to 2, 4, and 6 h of ischemia and to the same ischemia periods followed by 1 h of reperfusion. All purine intermediates from ATP to uric acid were determined in skeletal muscle with a high-performance liquid chromatography (HPLC) system. The major metabolic event during ischemia is to temporarily save the nucleotide pool as inosine-5'-monophosphate (IMP. On restitution of the circulation as the energy state recovers, the IMP is converted back to AMP via the purine nucleotide cycle. Six hours of ischemia is associated with irreversible damage and no recovery fo the adenine nucleotides on reperfusion. Fast-twitch muscles appear to be more susceptible than slow-twitch muscles in response to ischemia and reperfusion. A severalfold increase of intracellular hypoxanthine occurred during ischemia, whereas uric acid formation is observed only after reperfusion. These findings are discussed in relation to the proposed role of xanthine oxidase, as an enzyme generating tissue-injurious oxygen free radicals.
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PMID:Purine metabolism after in vivo ischemia and reperfusion in rat skeletal muscle. 236 Jun 63

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