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)

Sublethal ischemic challenges can protect neurons against a second, more severe hypoxic insult. We report here that nonlethal chemical ischemia induces a transient alteration of NMDA receptors in rat cortical neurons in culture. Cells were incubated with 3 mM KCN in a glucose-free solution for 90 min. Analysis of NMDA receptor unitary events in patches excised from KCN-treated neurons showed an increased incidence of a small conductance channel 24 h after chemical ischemia. Whole-cell recordings of NMDA-induced currents 1 day after cyanide exposure revealed a significant increase in voltage-dependent extracellular Mg(2+) block compared with untreated neurons. The block reverted to control levels within 48 h. Both of these changes in the NMDA receptor could decrease the overall current flowing through the channel. Message levels for the NMDA receptor subunits NR1, NR2A, and NR2B were not different between the chemically challenged neurons and control cells, whereas NR2C message was barely detectable in either group. These results suggest that the alterations in NMDA receptor properties after KCN exposure may contribute to the molecular mechanisms that are activated in neurons to withstand lethal ischemic events in the brain after preconditioning.
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PMID:Alterations of N-methyl-D-aspartate receptor properties after chemical ischemia. 1104 90

Yawing was induced by microinjections of L-glutamate, cyanide and a nitric oxide-releasing compound (NOC12) into the paraventricular nucleus of the hypothalamus (PVN) in anesthetized, spontaneously breathing rats. To evaluate physiological aspects of yawning, we monitored intercostal electromyogram (EMG) as an index of inspiratory activity, digastric EMG, blood pressure and electrocorticogram (ECoG). Microinjection of L-glutamate in the medial parvocellular subdivision (mp) elicited a stereotyped yawning response, i.e. an initial depressor response and an arousal shift in ECoG followed by a single large inspiration with mouth opening. The same sequential events were observed during spontaneous yawning, indicating that the mp is responsible for triggering yawning. Microinjection of cyanide into the mp caused the same yawning responses as the ones elicited by microinjection of L-glutamate, suggesting that the mp is sensitive to chemical hypoxia or ischemia within the PVN. Microinjection of NOC12 into the mp elicited a single large inspiration with a variable onset delay, suggesting that diffusible nitric oxide (NO) within the mp may act as a paracrine agent to cause a yawning response. We hypothesize that the mp of the PVN contains an oxygen sensor that causes a yawning response.
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PMID:Yawning responses induced by local hypoxia in the paraventricular nucleus of the rat. 1109 65

Different tissues display distinct sensitivities to defective mitochondrial oxidative phosphorylation (OXPHOS). Tissues highly dependent on oxygen such as the cardiac muscle, skeletal and smooth muscle, the central and peripheral nervous system, the kidney, and the insulin-producing pancreatic beta-cell are especially susceptible to defective OXPHOS. There is evidence that defective OXPHOS plays an important role in atherogenesis, in the pathogenesis of Alzheimer's disease, Parkinson's disease, diabetes, and aging. Defective OXPHOS may be caused by abnormal mitochondrial biosynthesis due to inherited or acquired mutations in the nuclear (n) or mitochondrial (mt) deoxyribonucleic acid (DNA). For instance, the presence of a mutation of the mtDNA in the pancreatic beta-cell impairs adenosine triphosphate (ATP) generation and insulin synthesis. The nuclear genome controls mitochondrial biosynthesis, but mtDNA has a much higher mutation rate than nDNA because it lacks histones and is exposed to the radical oxygen species (ROS) generated by the electron transport chain, and the mtDNA repair system is limited. Defective OXPHOS may be caused by insufficient fuel supply, by defective electron transport chain enzymes (Complexes I - IV), lack of the electron carrier coenzyme Q10, lack of oxygen due to ischemia or anemia, or excessive membrane leakage, resulting in insufficient mitochondrial inner membrane potential for ATP synthesis by the F0F1-ATPase. Human tissues can counteract OXPHOS defects by stimulating mitochondrial biosynthesis; however, above a certain threshold the lack of ATP causes cell death. Many agents affect OXPHOS. Several nonsteroidal anti-inflammatory drugs (NSAIDs) inhibit or uncouple OXPHOS and induce the 'topical' phase of gastrointestinal ulcer formation. Uncoupled mitochondria reduce cell viability. The Helicobacter pylori induces uncoupling. The uncoupling that opens the membrane pores can activate apoptosis. Cholic acid in experimental atherogenic diets inhibits Complex IV, cocaine inhibits Complex I, the poliovirus inhibits Complex II, ceramide inhibits Complex III, azide, cyanide, chloroform, and methamphetamine inhibit Complex IV. Ethanol abuse and antiviral nucleoside analogue therapy inhibit mtDNA replication. By contrast, melatonin stimulates Complexes I and IV and Gingko biloba stimulates Complexes I and III. Oral Q10 supplementation is effective in treating cardiomyopathies and in restoring plasma levels reduced by the statin type of cholesterol-lowering drugs.
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PMID:Mitochondrial medicine--molecular pathology of defective oxidative phosphorylation. 1131 62

While ischemia, hypoxic hypoxia, and carbon monoxide (CO) have received extensive study designed to characterize mechanisms by which they disrupt cochlear function, little data are available concerning cyanide's potential to disrupt auditory function. In this study, disruption of the compound action potential (CAP) and endocochlear potential (EP) by cyanide and CO was compared in rats treated with potassium cyanide (KCN) (7 mg/kg ip), saline, CO (35 ml/kg ip), and air. Acute KCN administration significantly suppressed CAP and EP transiently. The effect was seen initially on EP with CAP impairment occurring a few minutes later. Acute CO injection also suppressed the CAP significantly, but the effect was far smaller, occurred later in time, and lasted longer than the effect of KCN. The effect of CO on EP was equivocal. There was a good correspondence between blood cyanide levels and impairment of cochlear function; carboxyhemoglobin (HbCO) levels were elevated during the period when cochlear function was impaired, but recovery of cochlear function preceded the return of normal oxyhemoglobin. Both KCN and CO had somewhat preferential effects on high-frequency tones. Repeated cyanide administration caused a persistent CAP threshold elevation despite the rapid recovery of EP and CAP observed following acute KCN administration. The data suggest that acute KCN administration has a prominent disruptive effect at the stria vascularis presumably by disrupting the electron transport chain in this metabolically active structure. The principal target for acute CO ototoxicity in the cochlea is probably not the stria vascularis.
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PMID:Disruption of cochlear potentials by chemical asphyxiants. Cyanide and carbon monoxide. 1134 33

Inhibition of inward rectifier K(+) channels under ischemic conditions may contribute to electrophysiological consequences of ischemia such as cardiac arrhythmia. Ischemia causes metabolic inhibition, and the use of metabolic inhibitors is one experimental method of simulating ischemia. The effects of metabolic inhibitors on the activity of inward rectifier K(+) channels K(ir)2.1, K(ir)2.2, and K(ir)2.3 were studied by heterologous expression in Xenopus oocytes and two-electrode voltage clamp. 10 microm carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) inhibited K(ir)2.2 and K(ir)2.3 currents but was without effect on K(ir)2.1 currents. The rate of decline of current in FCCP was faster for K(ir)2.3 than for K(ir)2.2. K(ir)2.3 was inhibited by 3 mm sodium azide (NaN(3)), whereas K(ir)2.1 and K(ir)2.2 were not. K(ir)2.2 was inhibited by 10 mm NaN(3). All three of these inward rectifiers were inhibited by lowering the pH of the solution perfusing inside-out membrane patches. K(ir)2.3 was most sensitive to pH (pK = 6.9), whereas K(ir)2.1 was least sensitive (pK = 5.9). For K(ir)2.2 the pK was 6.2. These results demonstrate the differential sensitivity of these inward rectifiers to metabolic inhibition and internal pH. The electrophysiological response of a particular cell type to ischemia may depend on the relative expression levels of different inward rectifier genes.
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PMID:Differential sensitivity of inward rectifier K+ channels to metabolic inhibitors. 1211 13

We found that isolated guinea pig spinal cord white matter is resistant to acute oxygen-glucose deprivation. Sixty minutes of oxygen-glucose deprivation resulted in a 60% reduction of compound action potential (CAP) conductance, and there was a near complete recovery after 60 min reperfusion. Corresponding horseradish peroxidase-exclusion assay showed little axonal membrane damage. To further deprive the axons of metabolic substrate, we added 2 mM sodium cyanide or 2 mM sodium azide, both mitochondrial suppressors, to the ischemic medium, which completely abolished CAP and resulted in a 15 to approximately 30% recovery postreperfusion. Both compounds preferentially reduced the conductance of large diameter axons. We suggest the residual ATP in our ischemic model can protect anatomic integrity and physiological functioning of spinal axons following ischemic insult. This further suggests that oxygen-glucose deprivation alone cannot be solely responsible for short-term functional and anatomic damage. The damaging effects of ischemia in vivo may be mediated by factors originating from the gray matter of the cord or other systemic factors; both were largely eliminated in our in vitro white matter preparation.
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PMID:Resistance of isolated mammalian spinal cord white matter to oxygen-glucose deprivation. 1217 54

Anoxic/ischemic neuronal death is usually assessed in cell cultures or in vivo within a time window of 24 h to several days using the nucleic acid stain propidium iodide or histological techniques. Accordingly, there is limited information on the time course of such neuronal death. We loaded acute rat brain stem slices with propidium iodide for dynamic fluorometric recording of metabolic arrest-related cell death in the dorsal vagal nucleus. This model was chosen because dorsal vagal neurons show a graded response to metabolic inhibition: anoxia and aglycemia cause a sustained hyperpolarization, whereas ischemia induces a glutamate-mediated, irreversible depolarization. We found that the number of propidium iodide-labeled cells increased from 27% to 43% of total cell count within 1-7 h after preparation of slices. Compared with these untreated control slices, cyanide-induced anoxia (30 min) or aglycemia (1 h) did not cause further cell death, whereas 3-h aglycemia destroyed an additional 13% of cells. Ischemia (1 h) due to cyanide plus iodoacetate immediately labeled an additional 20% of cells, and an additional 48% of cells were destroyed within the following 3 h of postischemia. Continuous recording of propidium iodide fluorescence showed that loss of membrane integrity started within 25 min after onset of the ischemic depolarization and the concomitant intracellular Ca(2+) rise. The results show that propidium iodide can be used to monitor cell death in acute brain slices. Our findings suggest that pronounced cell death occurs within a period of 1-4 h after onset of metabolic arrest and is apparently due to necrotic/oncotic mechanisms.
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PMID:Dynamic recording of cell death in the in vitro dorsal vagal nucleus of rats in response to metabolic arrest. 1252 1

In this brief review the antioxidative actions of melatonin are summarized and they are discussed relative to several models of oxidative neurotoxicity. Melatonin is a ubiquitously acting antioxidant. It has been shown to scavenge the hydroxyl radical, peroxyl radical, singlet oxygen and the peroxynitrite anion; secondarily, it also scavenges the superoxide anion radical. In addition, melatonin reportedly stimulates a number of antioxidative enzymes including glutathione peroxidase, glutathione reductase and glucose-6-phosphate dehydrogenase. On the other hand, melatonin inhibits the pro-oxidative enzyme nitric oxide synthase. Besides these actions which help to resist oxidative damage, melatonin prevents membrane rigidity, reduces polymorphonuclear cell infiltration into damaged tissue, limits the adhesion of leucocytes to endothelial cells, thereby increasing blood flow and reducing edema. Some or all of these actions may have been operative in the experimental models of oxidative neurotoxicity that were improved by melatonin treatment. In brief, melatonin has been found to protect the CNS from beta-amyloid toxicity, experimental models of Parkinsonism, excitotoxicity, nitric oxide toxicity, aminolevulinic acid, lipopolysaccharide, hyperbaric hyperoxia, L-cysteine, cyanide and ischemia/reperfusion injury.
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PMID:Oxidative toxicity in models of neurodegeneration: responses to melatonin. 1267 8

Cell swelling may contribute to acute cell injury subsequent to ischemia/reperfusion. The potential role of mitochondrial uncoupling and the resultant mitochondrial swelling, due to opening of the mitochondrial permeability transition pore (MPTP), were examined in an in vitro ischemically pelleted isolated rabbit cardiomyocyte model using the protonophore, carbonyl cyanide m-chlorophenylhydrazone (CCCP) to uncouple mitochondria. Cyclosporin A (CsA) was employed to inhibit MPTP opening. Cell volume was determined by a cell-flotation, density-gradient assay, using bromododecane. Cell viability, subsequent to an osmotic stress, was determined by trypan blue permeability. Ischemic preconditioning (IPC) facilitated volume regulation following an osmotic stress. Ischemic-cell swelling was reduced by IPC. IPC protected ischemically pelleted cells, but CsA had no significant effects on injury or IPC protection. CCCP ischemia accelerated rates of ischemic contracture and injury, and abolished IPC protection. IPC protection was restored by CsA. In CCCP-ischemic-uncoupled cells, subjected to a reduced (170 mOsm) osmotic stress, CsA and IPC afforded independent and additive protection. Chelerythrine and 5-hydroxydecanoate (5-HD) blocked IPC, but did not reduce CsA protection. Electron microscopy confirmed that CCCP ischemia induced mitochondrial matrix swelling that was reduced by CsA. Cardioprotection by IPC and CsA was accompanied by proportional reductions in cell swelling. Morphometric analysis of the electron photomicrographs demonstrated that the mitochondrial volume fractions were significantly reduced in the CsA/CCCP (29.8 +/- 2.3%, P < 0.004) and IPC/CsA/CCCP (31.5 +/- 1.7%, P < 0.0008) groups as compared to the CCCP-ischemic group (40.5 +/- 1.7%) The IPC/CCCP group (39.5 +/- 4.2%) was not significantly different from the CCCP-ischemic group. NIM 811, a CsA analogue MPTP blocker with no calcineurin inhibitory activity, afforded protection similar to CsA. The results suggest that CsA protection may, in part, be mediated by reduction of mitochondrial swelling.
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PMID:Effects of CCCP-induced mitochondrial uncoupling and cyclosporin A on cell volume, cell injury and preconditioning protection of isolated rabbit cardiomyocytes. 1281 63

Preconditioning enables endogenous protection to repeated myocardial ischemia. However, the effect of preconditioning on beta1 adrenergic receptor (AR) signal remains controversial. We have recently developed receptor assay system using whole cells, in which overexpressed cell surface beta ARs can be readily quantitated without disrupting the cell. Using this technique, we examined the effects of chemical/metabolic ischemia on the beta1 AR sequestration and adenylyl cyclase activity. Isoproterenol treatment, but not forskolin treatment, of HEK293T cells overexpressing beta1 ARs led to a rapid decrease (within 2 hours) in the number of the cell surface receptor, which was negated in the presence of concanavalin A. Similarly, treatment of cells with potassium cyanide and 2-deoxy-D-glucose (chemical/metabolic ischemia) induced similar receptor sequestration. When isoproterenol was superimposed on chemical/metabolic ischemia, the degree of sequestration became greater. However, when cells were pre-exposed to potassium cyanide on the preceding day (chemical preconditioning), the sequestration induced by either isoproterenol or chemical/metabolic ischemia was attenuated. Adenylyl cyclase catalytic activity as assessed by stimulation with forskolin was decreased by chemical/metabolic ischemia but fully recovered after 24 hours, suggesting that chemical/metabolic ischemia treatment did not alter cell viability. Putting together, chemical/metabolic ischemia induced beta1 AR sequestration in a similar manner to isoproterenol. In addition, preconditioning prevented the beta1 AR sequestration induced by both isoproterenol and chemical/metabolic ischemia. Pre-conditioning may play a role in preserving the cell surface beta ARs by inhibiting the sequestration that is usually induced by an ischemic event or beta adrenergic stimulation.
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PMID:Ischemic preconditioning prevents ischemia-induced beta-adrenergic receptor sequestration. 1287 79

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