Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0917798 (cerebral ischemia)
17,036 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The possibility that cerebral ischemia or cerebral hypoxia may initiate a series of free radical reactions in brain tissue lipid constituents was explored by measuring sequential changes in chemiluminescence values and energy metabolism during brain hypoxia in the rat. Brain hypoxia was induced by means of arterial hypoxemia (PaO2 17-22 mmHg), normocapnia (PaCO2 28-38 mmHg) and normotension (MABP 100-140 mmHg). To obtain lowered PaO2, 4% O2--96% N2 mixed gas was used. Analysis of the chemiluminescence spectra for the purpose of luminous mechanism investigation was again attempted. No peroxidation occurred in the pre-hypoxic state since there were no photon counts. Chemiluminescence began to rise in the hypoxic state and remained at a high value in the post-hypoxic state. Specifically in the hypoxic state, the 3 min period showed 231 +/- 35 counts/10 sec X g (n = 5) and the 5 min period showed 154 +/- 62 (n = 19) counts/10 sec X g. In the post-hypoxic state, the 5 min period showed 217 +/- 79 counts/10 sec X g (n = 9) and the 30 min period showed a decrease similar to the pre-hypoxic state. The chemiluminescence spectroanalysis showed five peaks in wavelength at 480 nm, 520-530 nm, 570 nm, 620-640 nm and 680-700 nm. Sequential changes in energy metabolism revealed that hypoxia caused marked brain lactic acidosis, an increase in both ADP and pyruvate, and a fall in glucose. However, all metabolites recovered at 30 min in the post-hypoxic state, which suggests this was reversible brain hypoxia. Sequential changes in chemiluminescence values and energy metabolism imply the occurrence of free radical reaction in the hypoxic and post-hypoxic brain. The spectroanalysis reveals the luminous mechanism as follows: 1 delta g + 1 delta g----23O2 + h mu
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PMID:Chemiluminescence in hypoxic brain--the first report. Correlation between energy metabolism and free radical reaction. 650 18

To explore the possibility that cerebral ischemia or cerebral hypoxia may initiate a series of free radical reactions of brain tissue lipid constituents, we measured sequential change of chemiluminescence and energy metabolites during brain hypoxia in rat. The hypoxic brain was induced by arterial hypoxemia (PaO2 17-22 mmHg) with normocapnia (PaCO2 28-38 mmHg) and normotension (MABP 100-140 mmHg). 4% O2-96% N2 mixed gas was used as the replacement for obtaining lowered PaO2. We made another attempt to analyze chemiluminescence spectra on purpose of luminous mechanism investigation. No peroxidation occurred in prehypoxic state since there were no photon counts, however, chemiluminescence began to rise up in hypoxic state and remained high value in posthypoxic early state. Namely in hypoxic state, 3-min period showed 231 counts/10 sec X g and 5-min period showed 154 counts/10 sec X g. In posthypoxic state, 5-min period showed 217 counts/10 sec X g and 30-min period showed a similar decrease as prehypoxic state. The chemiluminescence spectroanalysis showed five peaks at 480 nm, 520-530 nm, 570 nm, 620-640 nm, 700 nm in wavelength. As to sequential changes of energy metabolism, hypoxia caused marked brain lactic acidosis, increase in ADP, pyruvate and a fall in glucose. However, all metabolites recovered at 30-min period in posthypoxic state, which suggests this was reversible brain hypoxia. A transition of chemiluminescence and energy metabolites suggests the occurrence of free radical reaction in hypoxic and posthypoxic brain. The spectroanalysis reveals the luminous mechanism as follows 1 delta g # 1 delta g----2(3)O(2) + h nu.
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PMID:[Chemiluminescence on hypoxic brain--the 1st report: relation between free radical reaction and energy metabolism]. 674 96

Respiratory activity of isolated rat brain mitochondria was measured following in vitro exposure to oxygen radicals. The radicals were generated by hypoxanthine and xanthine oxidase in the presence of a suitable iron chelate and caused a severe inhibition of respiration stimulated by phosphate plus ADP (with malate + glutamate as substrate). The damage could be prevented by catalase or high concentrations of mannitol, but not by superoxide dismutase. A similar effect was observed when hypoxanthine and xanthine oxidase were replaced by glucose and glucose oxidase or by hydrogen peroxide. Most of the findings indicate that the hydroxyl radical is the damaging agent. It is concluded that brain mitochondria exposed to oxygen radicals in vitro show an inhibition of respiratory activity similar to that reported by other investigators as occurring in mitochondria in vivo following transient cerebral ischemia. Therefore, oxygen radicals may contribute to this type of cell damage.
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PMID:Respiratory activity of isolated rat brain mitochondria following in vitro exposure to oxygen radicals. 684 68

The cerebral metabolic responses to perinatal hypoglycemia (blood glucose less than or equal to 1 mmol/l) combined with asphyxia were studied in paralyzed, lightly anesthetized newborn dogs. No major differences in heart rate, blood pressure or arterial acid-base balance between control and hypoglycemic animals occurred either prior to or during asphyxia. The electroencephalogram, unaltered by hypoglycermia alone, became isoelectric at the same intervals in both groups following respiratory arrest. Intravenous carbon black infusion at 5 min of asphyxia demonstrated no relationship between blood glucose level and cerebral perfusion (p > 0.05), whereas a positive correlation did exist between systemic blood pressure and cerebral perfusion (p < 0.01). During asphyxia, anaerobic glycolysis in brain was less enhanced in hypoglycemic dogs, resulting in a more rapid exhaustion of high-energy phosphate reserves (phosphocreatine, ATP and ADP). Thus, the cerebral metabolic responses to asphyxia superimposed upon hypoglycemia were the direct consequence of insufficient cerebral glucose stores coupled with deficient circulating glucose to brain. These metabolic disturbances were no more the result of cerebral ischemia than that which occurs during asphyxia alone. The findings also suggest that systemic physiological monitoring may be an inadequate means of appraising cerebral homeostasis during combined hypoglycemia ad hypoxia.
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PMID:Cerebral metabolism during hypoglycemia dn asphyxia in newborn dogs. 689 22

The objective of this study was to assess the relationship between the changes in the redox state of cytochrome oxidase (Cyt. ox.) and those of spontaneous EEG activity and cellular energy state during cerebral ischemia and recirculation. We induced 5-min forebrain ischemia by occluding the bilateral common carotid arteries in anesthetized gerbils. Redox changes of Cyt. ox. were monitored with near-infrared spectroscopy (NIRS) through the experiments. Cortical energy metabolites, ATP, ADP, and AMP, were also measured with high performance liquid chromatography (HPLC) during ischemia and recirculation. Ischemia immediately caused a rapid reduction of Cyt. ox., which paralleled to deterioration of spontaneous EEG activity and preceded significant changes in cellular energy state. Re-oxygenation of Cyt. ox. was observed just after recirculation, and paralleled to the recovery of cellular energy state. Spontaneous EEG activity did not recover even when all other NIRS parameters almost recovered during recirculation after 5-min ischemia. During clamping of the carotid artery, NIRS findings also correlated with those of somatosensory evoked potential (SEP). We concluded that, by means of monitoring redox changes of Cyt. ox., NIRS can detect non-invasively critical neuronal hypoxia prior to a significant impariment of cellular energy state caused by cerebral ischemia, and that NIRS can also detect recovery of oxidative phosphorylation during recirculation, which cannot be observed on EEG.
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PMID:[Near-infrared monitoring of cerebral oxygenation during cerebral ischemia]. 759 May 92

The present study investigated the effect of the administration of oxypurinol (40 mg/kg), an inhibitor of xanthine oxidase, on adenosine and adenine nucleotide levels in the rat brain during ischemia and reperfusion. The brains of the animals were microwaved before, at the end of a 20-min period of cerebral ischemia, and after 5, 10, 45, and 90 min of reperfusion. Cerebral ischemia was elicited by four-vessel occlusion with arterial hypotension to 45-50 mm Hg. Adenosine and adenine nucleotide levels in the oxypurinol-pretreated (administered intravenously 20 min before ischemia) rats were compared with those in nontreated animals exposed to the same periods of ischemia and reperfusion. Oxypurinol administration resulted in significantly elevated ATP levels at the end of ischemia and 5 min after ischemia, but not at 10 min after ischemia. ADP levels were also elevated, in comparison with those in the control rats, at the end of the ischemic period. Conversely, AMP levels were significantly reduced at the end of ischemia and during the initial (5 min) period of reperfusion. Adenosine levels were lower in oxypurinol-treated rats, during ischemia, and in the initial reperfusion phase. Oxypurinol administration resulted in a significant increase in the energy charge both during ischemia and after 5 min of reperfusion. Physiological indices, namely, time to recovery of mean arterial blood pressure and time to onset of respiration, were also shortened in the oxypurinol-treated animals. These beneficial effects of oxypurinol may have been a result of its purine-sparing (salvage) effects and of its ability to inhibit free radical formation by the enzyme xanthine oxidase. Preservation of high-energy phosphates during ischemia likely contributes to the cerebroprotective potency of oxypurinol.
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PMID:Oxypurinol-enhanced postischemic recovery of the rat brain involves preservation of adenine nucleotides. 772 3

Berberine (Ber) 20 mg.kg-1.d-1 for 1, 3, or 5 d inhibited platelet aggregation induced by ADP, arachidonic acid (AA) and collagen (Coll) in rats with 24 h reversible middle cerebral artery occlusion (MCAO), and the platelet adhesiveness was inhibited as well. Using radioimmunoassay method, the thromboxane B2(TXB2) and 6-keto-prostaglandin F1 alpha (6-keto-PGF1 alpha) contents in rat plasma were measured 24 h after MCAO. The results indicate that the TXB2 levels after drug treatment were lower than those in ischemia control rats, but the 6-keto-PGF1 alpha levels showed no obvious difference between the two groups. The same dose of Ber was also shown to inhibit thrombosis formation. This suggests that the decline of platelet aggregation and decrease of TXB2 content may be one of the important factors involved in the anti-cerebral ischemia effect of Ber.
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PMID:[Effects of berberine on platelet aggregation and plasma levels of TXB2 and 6-keto-PGF1 alpha in rats with reversible middle cerebral artery occlusion]. 778 38

Previous studies have shown that global cerebral ischemia induced by decapitation leads to the stimulated hydrolysis of poly-phosphoinositides. In this study, the decapitation model was used to further examine the temporal events related to metabolism of Ins(1,4,5)P3 and the release of diacylglycerols (DGs) and free fatty acids (FFAs) in the mouse brain. Since lithium administration is known to inhibit inositol monophosphatase activity in brain, the effects of acute lithium injection on Ins(1,4,5)P3 metabolism were also examined. Cerebral ischemia induced by decapitation of C57 Bl/6J mice resulted in transient increases of Ins(1,4,5)P3, Ins(1,4)P2 and Ins(4)P which peaked at 35, 65 and 125 s, respectively. The level of Ins(1)P, however, was not altered. Mice administered lithium by intraperitoneal injection (8 meq/kg for 4 h) gave rise to a 40- and 4-fold increase in levels of Ins(1)P, Ins(4)P, respectively, a 20% increase in levels of Ins(1,4)P2 but no apparent changes in the levels of Ins(1,4,5)P3. Decapitation also induced an increase in the levels of DGs and FFAs. Unlike the transient appearance of Ins(1,4,5)P3, however, DG levels increased steadily for 2 min and then reached a plateau whereas the FFAs showed a lag time of 35 s prior to a biphasic increase. During the initial 2 min after decapitation, there was a preferential increase in the DG species containing 18:0 and 20:4. Lithium administration did not alter the decapitation-induced release of DG and FFA. As expected, decapitation gave rise to a rapid decrease in the levels of phosphocreatine and ATP and the decline in ATP was marked by a transient appearance of ADP and a concomitant increase in AMP.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Metabolism of inositol 1,4,5-trisphosphate in mouse brain due to decapitation ischemic insult: effects of acute lithium administration and temporal relationship to diacylglycerols, free fatty acids and energy metabolites. 849 Jul 17

1. ATP-sensitive K+ channels (KATP) are activated either by decreased intracellular ATP content or ATP/ADP ratio during ischaemia. We examined the role of a cerebral KATP in arterial pressure regulation during acute cerebral ischaemia using SHR and WKY rats. Thirteen week old male SHR or WKY rats were anaesthetized with urethane, and arterial pressure and heart rate were recorded under an artificial ventilation. 2. Intracerebroventricular (i.c.v.) injections of glibenclamide, a specific inhibitor of KATP, elicited dose-dependent vasopressor responses in WKY with bilateral ligation of carotid arteries, whereas it caused smaller vasopressor responses in SHR than WKY. 3. Systemic administration of AVP V1 receptor antagonist, OPC-21268, abolished the vasopressor responses of i.c.v. injections of glibenclamide in WKY but not in SHR. 4. Intracerebroventricular injections of glibenclamide caused both the increase in plasma concentration of AVP and the decrease in pituitary AVP content in WKY with bilateral ligation of carotid arteries, whereas it elicited no significant change in plasma and pituitary concentration of AVP in SHR with bilateral ligation of carotid arteries. 5. Cerebral KATP may play a role in the protection of excess hypertension by inhibiting AVP release from the pituitary glands during acute ischaemia in WKY, but this mechanism might not work in SHR during acute cerebral ischaemia.
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PMID:Role of cerebral ATP-sensitive K+ channels in arterial pressure regulation during acute cerebral ischaemia in SHR and WKY rats. 907 49

The effects of an adenosine deaminase inhibitor (deoxycoformycin, 500 mu g/kg) and of an inhibitor of nucleoside transport (propentofylline, 10 mg/kg) on adenosine and adenine nucleotide levels in the ischemic rat brain were investigated. The brains of the rats were microwaved before, at the end of a 20 min period of cerebral ischemia (4 vessel occlusion + hypotension), or after 5, 10, 45, and 90 min of reperfusion. Deoxycoformycin increased brain adenosine levels during both ischemia and the initial phases of reperfusion. AMP levels were elevated during ischemia and after 5 min of reperfusion. ATP levels were elevated above those in the non-treated animals after 10 and 45 min of reperfusion. ADP levels were elevated above the non-drug controls at 90 min. These increases in ATP, ADP and AMP resulted in significant increases in total adenylates during ischemia, and after 10 min and 90 min of reperfusion. Propentofylline administration resulted in enhanced AMP levels during ischemia but did not alter adenosine or adenine nucleotide levels during reperfusion in comparison with non-treated controls.
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PMID:Effects of an inhibitor of adenosine deaminase, deoxycoformycin, and of nucleoside transport, propentofylline, on post-ischemic recovery of adenine nucleotides in rat brain. 913 41


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