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

The effects of selective adenosine receptor agonists [N6-cyclopentyladenosine (CPA) and N-ethylcarboxamidoadenosine (NECA)] and antagonists [8-cyclopentyl-1,3-dipropylxanthine (DPCPX) and 9-chloro-2-(2-furanyl)-5,6-dihydro-1,2,4-triazolo[1,5-c]quinazoline-5-im ine (CGS-15943A)] on aspartate and glutamate release from the ischemic rat cerebral cortex were studied with the cortical cup technique. Cerebral ischemia (for 20 min) was elicited by four-vessel occlusion. Excitatory amino acid releases were compared from control ischemic rats and drug-treated rats. Basal levels of aspartate and glutamate release were not greatly affected by pretreatment with the adenosine receptor agonists or antagonists. However, CPA (10(-10) M) and NECA (10(-9) M) significantly inhibited the ischemia-evoked release of aspartate and glutamate into cortical superfusates. The ability to block ischemia-evoked release of excitatory amino acids was not evident at higher concentrations of CPA (10(-6) M) or NECA (10(-5) M). The selective A1 receptor antagonist DPCPX also had no effect on release when administered at a low dosage (0.01 mg/kg, i.p.) but blocked the ischemia-evoked release of aspartate and glutamate at a higher dosage (0.1 mg/kg). Evoked release was inhibited by the selective A2 receptor antagonist CGS-15943A (0.1 mg/kg, i.p.). Thus, adenosine and its analogs may suppress ischemia-evoked release of excitatory neurotransmitter amino acids via high-affinity A1 receptors, whereas coactivation of lower-affinity A2 receptors may block (or reverse) the A1-mediated response.
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PMID:Excitatory transmitter amino acid release from the ischemic rat cerebral cortex: effects of adenosine receptor agonists and antagonists. 134 22

The excitotoxic hypothesis suggests that cerebral ischemic damage results in part from the accumulation of the excitatory and potentially toxic neurotransmitters glutamate and aspartate. Adenosine, which also increases during cerebral ischemia, is proposed to inhibit neurotransmitter release. The purpose of this study was to determine if adenosine receptor blockade exacerbates the accumulation of glutamate and aspartate during cerebral ischemia. Microdialysis probes, implanted bilaterally in the caudate nucleus of halothane-anesthetized rats, were used to (1) assess changes in interstitial fluid (ISF) glutamate, aspartate, adenosine, and adenosine metabolites; (2) measure local cerebral blood flow (H2 clearance); and (3) deliver 8-(p-sulfophenyl)theophylline (SPT), an adenosine receptor antagonist, locally to the brain. The probe on one side of the brain was perfused with artificial cerebrospinal fluid (CSF) containing 10(-3) M SPT, while the probe on the opposite side received only artificial CSF. Animals were exposed to 20 min of ischemia (carotid occlusion+arterial blood pressure = 50 mm Hg) followed by 60 min of reperfusion. Dialysate glutamate and aspartate increased during and after cerebral ischemia, but were increased to a greater extent in the presence of adenosine receptor blockade. Likewise, the increase in dialysate adenosine and adenosine metabolites was enhanced on the side of locally administered SPT. These data suggest that endogenous adenosine attenuates the accumulation of glutamate and aspartate during cerebral ischemia.
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PMID:Adenosine receptor blockade augments interstitial fluid levels of excitatory amino acids during cerebral ischemia. 135 4

We examined the anti-infarct effect of ischemic preconditioning in the rat heart. All hearts were subjected to 30 min of regional coronary ischemia and 2 h of reperfusion. Infarct size was determined by tetrazolium. The control group had an average infarct size of 31% of the risk zone. Three 5-min cycles of preconditioning ischemia limited the infarct size to 3.7%. Neither the adenosine receptor blocker PD 115,199 nor the ATP-sensitive potassium channel blocker, glibenclamide, could block this protection. Intracoronary adenosine A1-receptor agonist 2-chloro-N6-cyclopentyladenosine offered a significant anti-infarct protection to the isolated rat heart, however. Although one 5-min cycle of preconditioning did not protect the rat heart from infarction (31% infarction in risk zone), it did attenuate arrhythmias. We conclude that 1) the rat heart can be preconditioned, which argues against mitochondrial adenosinetriphosphatase being the mechanism of preconditioning; 2) the threshold for preconditioning is higher in rat than rabbit or dog; 3) a role for adenosine in preconditioning was only partially supported; and 4) a role for ATP-sensitive potassium channels was not supported.
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PMID:Ischemic preconditioning protects against infarction in rat heart. 141 59

The A1-adenosine receptor agonist, R-phenylisopropyl-adenosine (R-PIA), demonstrated antinociceptive properties in animal studies after intrathecal administration. In the evaluation of a drug for possible spinal injection in humans, the effects of intrathecal R-PIA on spinal cord blood flow (SCBF) were investigated using the laser-Doppler flow-metry technique in anesthetized rats. In low doses (0.1-1 nmol), no change in SCBF was recorded, whereas larger doses (10-100 nmol) caused a significant increase in SCBF. No change in systemic arterial blood pressure could be seen, except for a decrease after administration of the largest dose of R-PIA (100 nmol). It is concluded that R-PIA in doses of 10 nmol and larger induces an increase in SCBF after intrathecal injection in anesthetized rats and that an increase in blood flow is seen before any effect on the systemic circulation is detected. It can also be deduced that the antinociceptive effects of R-PIA after intrathecal injection are not a consequence of spinal ischemia and that disturbances in local blood flow cannot be expected to constitute a neurotoxic factor.
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PMID:R-phenylisopropyl-adenosine increases spinal cord blood flow after intrathecal injection in the rat. 144 16

The adhesion of leukocytes to the endothelium of postcapillary venules hallmarks a key event in ischemia-reperfusion injury. Adenosine has been shown to protect from postischemic reperfusion injury, presumably through inhibition of postischemic leukocyte-endothelial interaction. This study was performed to investigate in vivo by which receptors the effect of adenosine on postischemic leukocyte-endothelium interaction is mediated. The hamster dorsal skinfold model and fluorescence microscopy were used for intravital investigation of red cell velocity, vessel diameter, and leukocyte-endothelium interaction in postcapillary venules of a thin striated skin muscle. Leukocytes were stained in vivo with acridine orange (0.5 mg kg-1 min-1 i.v.). Parameters were assessed prior to induction of 4 h ischemia to the muscle tissue and 0.5 h, 2 h, and 24 h after reperfusion. Adenosine, the adenosine A1-selective agonist 2-chloro-N6-cyclopentyladenosine (CCPA), the A2-selective agonist CGS 21,680, the non-selective adenosine receptor antagonist xanthine amine congener (XAC), and the adenosine uptake blocker S-(p-nitrobenzyl)-6-thioinosine (NBTI) were infused via jugular vein starting 15 min prior to release of ischemia until 0.5 h after reperfusion. Adenosine and CGS 21,680 significantly reduced postischemic leukocyte-endothelium interaction 0.5 h after reperfusion (p less than 0.01), while no inhibitory effect was observed with CCPA. Coadministration of XAC blocked the inhibitory effects of adenosine. Infusion of NBTI alone effectively decreased postischemic leukocyte-endothelium interaction. These findings indicate that adenosine reduces post-ischemic leukocyte-endothelium interaction via A2 receptor and suggest a protective role of endogenous adenosine during ischemia-reperfusion.
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PMID:Reduction of postischemic leukocyte-endothelium interaction by adenosine via A2 receptor. 144 86

The effects of pretreatment with the nucleoside transport inhibitor lidoflazine on repeated ischemia-reperfusion injury induced by normothermic intermittent aortic crossclamping were studied in canine hearts. Eighteen mongrel dogs were allocated to three groups: placebo (n = 6), lidoflazine (1 mg/kg) (n = 6), and lidoflazine (1 mg/kg) plus the adenosine receptor blocker aminophylline (7 mg/kg) (n = 6). Pretreatment was performed intravenously during 15 minutes before extracorporeal circulation. All hearts were subjected to four intervals of 15 minutes of global ischemia each followed by 10 minutes of reperfusion. After weaning from extracorporeal circulation, functional recovery was followed for 1 hour. In the lidoflazine group, myocardial adenosine content (0.25 +/- 0.06 mumol/gm dry weight) was 3.5 times higher than that in the control group (0.07 +/- 0.03 mumol/gm dry weight; p < 0.05) at the end of the last aortic crossclamping. The release of adenosine from the myocardium during each reperfusion period was significantly higher than that in the control group (p < 0.05). Myocardial extraction of lactate was normalized at every reperfusion interval in the lidoflazine group but not in the control group (p < 0.05). In the lidoflazine group functional recovery was significantly better than that in the control group. Positive rate of rise of pressure, negative rate of rise of pressure, and cardiac output recovered to, respectively, 150% +/- 19%, 82% +/- 8%, and 131% +/- 15% in the lidoflazine group versus, respectively, 37% +/- 9%, 23% +/- 7%, and 29% +/- 8% in the control group (p < 0.001) at 1 hour after extracorporeal circulation. When the adenosine receptor blocker aminophylline was administered in association with lidoflazine, protection dropped significantly: positive and negative rate of rise of pressure and cardiac output were, respectively, 58% +/- 8%, 46% +/- 9%, and 67% +/- 16% at 1 hour after extracorporeal circulation (p < 0.05 versus lidoflazine alone). These results suggest that the cardioprotective effects of lidoflazine are at least in part mediated by adenosine receptor stimulation via nucleoside transport inhibition-induced accumulation of endogenous adenosine in the myocardium.
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PMID:Nucleoside transport inhibition mediates lidoflazine-induced cardioprotection during intermittent aortic crossclamping. 145 24

Recent experimental data indicate a probable role of adenosine as an endogenous neuroprotective substance in brain ischemia. This nucleoside is rapidly formed during ischemia as a result of intracellular breakdown of ATP and it is subsequently transported into the extracellular space. With use of microdialysis and other techniques, a massive increase of interstitial adenosine has been measured during ischemia in different brain areas. Adenosine acts through two subtypes of receptors, A1 and A2, which are located on neurons, glial cells, blood vessels, platelets, and leukocytes and are linked via G-proteins to different effector systems such as adenylate cyclase and membrane ion channels. There is a very high density of A1-receptors in the hippocampus, an area with specific vulnerability to ischemia. In different in vivo and in vitro models of brain ischemia, the pharmacological manipulation of the adenosine system by adenosine receptor antagonists tended to aggravate ischemic brain damage, whereas the reinforcement of adenosine action by receptor agonists or inhibitors of cellular reuptake and inactivation showed neuroprotection. The up-regulation of adenosine A1-receptor number and affinity by chronic preadministration of the competitive antagonist caffeine also attenuated ischemic brain damage. The mechanisms underlying the neuroprotective effects of adenosine seem to involve both types of adenosine receptors, A1 and A2, but the A1-mediated pre- and postsynaptic neuromodulation may be of special importance. By inhibiting neuronal Ca2+ influx, adenosine counteracts the presynaptic release of the potentially excitotoxic neurotransmitters glutamate and aspartate, which may impair intracellular Ca2+ homeostasis via metabotrophic glutamate receptors or induce uncontrolled membrane depolarization via ion channel-linked glutamate receptors, especially of the N-methyl-D-aspartate (NMDA) type. In addition, adenosine directly stabilizes the neuronal membrane potential by increasing the conductance for K+ and Cl- ions, thereby counteracting excessive membrane depolarization. The latter triggers a number of pathological events including blockade of voltage-sensitive K+ currents, increase of NMDA receptor-mediated Ca2+ influx, and presumably also impairment of glutamate uptake by astrocytes. In the way of a vicious cycle, all these factors again tend to enhance extracellular glutamate levels and membrane depolarization, finally leading to cytotoxic calcium loading and neuronal cell death. In addition to its important neuromodulatory effects, which tend to reduce energy demand of the brain, adenosine acting via A2-receptors in brain vessels, platelets, and neutrophilic granulocytes may improve the cerebral microcirculation and thus oxygen and substrate supply to the tissue. There is evidence that the functional state of adenosine receptors is impaired during ischemia, limiting the time window of the adenosine action.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Adenosine and brain ischemia. 148 19

The effects of CPA (a selective A1 receptor agonist), NECA (a mixed A1 and A2 receptor agonist), and CGS 21680 (a selective A2 receptor agonist) on the ischemia-evoked release of gamma-aminobutyric acid (GABA) from rat cerebral cortex was investigated with the cortical cup technique. Cerebral ischemia (20 min) was elicited by four vessel occlusion. In control animals, superfusate GABA increased from a basal level of 206 +/- 26 nM (mean +/- S.E.M., n = 18) to 10,748 +/- 3,876 nM during the reperfusion period. Pretreatment with adenosine receptor agonists failed to affect basal levels of GABA release. However, CPA (10(-10) M), NECA (10(-9) M), and CGS 21680 (10(-8) M) significantly suppressed the ischemia-evoked release of GABA. The ability to block the ischemia-evoked release of GABA was not evident when the adenosine receptor agonists were administered at higher concentrations. Thus, the selective activation of either A1 or high-affinity A2a adenosine receptors results in an inhibition of ischemia-evoked GABA release.
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PMID:Adenosine receptor agonists inhibit the release of gamma-aminobutyric acid (GABA) from the ischemic rat cerebral cortex. 149 81

Calcium was localized ultrastructurally with the use of the modified oxalate-pyroantimonate reaction in the CA1 region of rat hippocampal slices. Ten-minute ischemia (incubation with anoxic and glucose-free medium) followed by 30 min reoxygenation resulted in mitochondrial calcium sequestration and ultrastructural damage. The addition of the adenosine receptor antagonist, theophylline, worsened the ischemia-induced morphological changes and particularly exaggerated the Ca2+ loading in the postsynaptic dendrites. In contrast, adenosine protected against ischemia-induced changes. The results suggest that adenosine exerts its neuroprotective action largely by maintaining intracellular calcium-homeostasis.
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PMID:Ultrastructural localization of calcium in ischemic hippocampal slices: the influence of adenosine and theophylline. 156 44

Phospholipid metabolism is altered during ischemia and post-ischemic reperfusion. Past studies demonstrating elevated myocardial free fatty acid and lysophospholipid content infer accelerated phospholipid degradation involving phospholipase A activity. Recently, ischemic and post-ischemic reperfusion (reperfusion) have been shown to affect levels of phosphoinositide (PPI) degradation products. Considering the role of PPI turnover in regulation of cellular calcium homeostasis, our laboratory and others have suggested that alteration in the metabolism of the inositol phospholipids could play a role in the development of ischemia-induced calcium overload injury. Using an isolated rat heart model (Langendorff perfusion), this study examines the effect of global ischemia and reperfusion on ventricular phosphoinositide-specific phospholipase C (PLC) activity and PLA2 activity. The primary purpose was to determine if ischemia and reperfusion-induced changes in PLC activity could explain previously observed changes in PPI degradation products, and whether PLC and PLA2 activities were similarly or differentially altered by ischemia and reperfusion. PLC and PLA2 activities were measured in cytosolic and total membrane fractions from control (perfused), ischemic (5, 10, 30, and 60 min), and post-ischemic reperfused ventricular tissue. Phospholipase activity was determined under optimal in vitro conditions using exogenous radiolabeled substrates. Alterations in membrane-associated PPI-PLC activity correlated with reported ischemia and reperfusion-induced changes in ventricular content of PPI metabolites. Membrane PLC activity increased slightly at 5 min of ischemia, decreased significantly at 10 min of ischemia, and continued to decrease with longer duration of ischemia (73% of control after 60 min). Cytosolic PPI-PLC activity was decreased at 5 min, and then significantly increased by longer durations of ischemia, while cytosolic PLA2 activity was reduced at all time points. Pretreatment with muscarinic, alpha 1-adrenergic, beta-adrenergic, and adenosine receptor blockers did not alter ischemia-elicited changes in PLC activity. Reperfusion caused a 140% to 200% rise in the activities of all phospholipases in all fractions after 40 min of ischemia, but not after 10 min of ischemia. Results suggest 1) ischemia and reperfusion-elicited alterations in membrane-associated PPI-PLC activity can explain previously observed changes in phosphoinositide turnover metabolites, 2) cytosolic and membrane-associated PPI-PLC and PLA2 activities are not uniformly affected by ischemia, 3) reperfusion following ischemia of sufficient duration initiates uniform activation of PIP2-PLC and PLA2, and 4) because ischemia and reperfusion-induced changes in phospholipase activity can be detected under optimal in vitro assay conditions (removed from the in vivo ischemic microenvironment), it is likely that the enzymes themselves have been altered.
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PMID:Changes in phosphoinositide-specific phospholipase C and phospholipase A2 activity in ischemic and reperfused rat heart. 159 Jul 34


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