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)

Toxicity of t-butylhydroperoxide (t-BuOOH) was studied at different steady state O2 concentrations under conditions at which O2 deficiency alone did not cause cell death. t-BuOOH-induced cell death was more rapid in hypoxic than normoxic cells; the maximal rate of cell death occurred in anoxic cells. t-BuOOH elimination was independent of O2 concentration and was complete within 15 min; t-Butanol was produced at the same rate and was the only product detected by gas chromatography. Measurement of radical production by formation of adducts of the spin-trapping agent N-tert-butylphenylnitrone showed that the amount of radicals trapped was 0.02% of the amount of peroxide added and was the same under anoxic and oxygenated (214 microM O2) conditions. These results show that the O2 dependence of t-BuOOH-induced toxicity is not related to quantitative alterations in its metabolism. Lipid peroxidation was lowest in anoxic cells and increased as the O2 concentration was increased to 1.07 mM O2, showing that enhanced toxicity during hypoxia and anoxia was not due to enhanced lipid peroxidation. In contrast, O2 deficiency impaired the ability of cells to maintain and recovery GSH and NADPH pools after addition of t-BuOOH. GSH was decreased to a greater extent in anoxic cells than in normoxic cells, and the GSH content remained lower in these cells for up to 30 min. This decrease was due both to a decrease in the rate of synthesis and to decreased supply of the NADPH needed for the reduction of GSSG. Taken together, these results show that O2 deficiency has little effect on metabolism of t-BuOOH but impairs the ability of cells to maintain cellular GSH and renders them more susceptible to injury from oxidizing agents. This suggests that oxidative injury under hypoxia or following ischemia may not require a marked stimulation in generation of oxidative species but may occur as a consequence of the impaired ability to tolerate or repair oxidative injury.
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PMID:Effect of hypoxia on tert-butylhydroperoxide-induced oxidative injury in hepatocytes. 341 29

We investigated if the loss of nicotinamide coenzymes in ischemic-infarcted myocardium may be responsible for the transition from reversibly ischemic to irreversibly infarcted cell damage. The LAD was occluded in 6 dogs for 4 h. Transmural needle biopsies were taken from he ischemic-infarcted region after 1/2, 1, 11/2, 2, and 4 h of ischemia and further divided into subepicardial and subendocardial halves. At each time interval the concentration of the nicotinamide coenzymes NAD, NADH, and NADPH were measured, and the degree of cellular injury was evaluated by electron microscopy. The glycohydrolase activity (EC 3.2.2.5), the enzyme which splits NAD, was determined in brain, myocardium, kidney, and skeletal muscle of 4 rats. Total NAD, the sum of NAD and NADH, started to decrease significantly in the ischemic subendocardium 1 h after onset of ischemia. Degradation of NADPH occurred later. Loss ot total NAD was about 60-70% when electron microscopy diagnosed irreversible cell injury. The glycohydrolase activity was the highest in brain followed by myocardium, kidney, and skeletal muscle, reflecting the different tolerances of these tissues towards ischemia. The key mechanism for ischemic injury seems to be the tissue acidosis which activates the glycohydrolase leading to a loss of the vital coenzymes.
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PMID:Loss of canine myocardial nicotinamide adenine dinucleotides determines the transition from reversible to irreversible ischemic damage of myocardial cells. 627 93

We strongly support the original intriguing hypothesis of Hearse et al. that the oxygen paradox and the calcium paradox are facets of the same problem. We would propose that the major similarity is a final common pathway leading to intracellular calcium overload and the sequelae of the resultant increase in intracellular calcium. In addition, we would propose that the oxygen paradox and ischemic/reperfusion injury are also facets of the same problem with the major similarity being the reintroduction of molecular oxygen to a previously hypoxic myocardium. Finally, we would suggest that the common pathway leading to intracellular calcium overload in the oxygen paradox and ischemic/reperfusion injury and to a lesser extent the calcium paradox involves the generation of oxygen free radicals. The source of oxygen free radical generation in the calcium paradox is perhaps less obvious than in the oxygen paradox. It is proposed that during calcium-free perfusion, calcium is leached from the plasmalemma of the myocyte. There is a resulting increase in membrane fluidity. Within the plasmalemma are a number of calcium sensitive phospholipases. Upon reperfusion with a calcium replete medium, calcium could pool around these membrane bound phospholipases initiating a chain reaction of lipid peroxidation which actually is perpetuated by free radical generation (Equations 5A-5C). Lipid peroxidation opens channels within the plasmalemma rendering a 'leaky' sarcolemma. It is through these channels that calcium could flow down its concentration gradient into the cell. The increased calcium accumulation at the mitochondria would lead to an uncoupling of oxidative phosphorylation. With depleted energy stores, the mitochondria and sarcoplasmic reticulum no longer serve as calcium sinks. This would contribute to the calcium overload seen upon reperfusion. The role of oxygen free radical production would appear to occur during the hypoxic phase of the oxygen paradox and the ischemic phase of ischemic/reperfusion injury and during the reoxygenation/reperfusion phases. With the onset of hypoxia and/or myocardial ischemia there is an increase in reducing equivalents, disturbance and dissociation of intramitochondrial electron transport and release of ubisemiquinone, flavoproteins and superoxide radicals. The increase in reducing equivalents includes NADPH and, in ischemia, catecholamines, hypoxanthine and an increase on xanthine oxidase activity. All of these substrates are capable of participating in free radical production. This increase in free radical production in ischemic tissue is enhanced by acidosis which in the ischemic and hypoxic myocardium approaches pH 6.0-6.4.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Molecular oxygen: friend and foe. The role of the oxygen free radical system in the calcium paradox, the oxygen paradox and ischemia/reperfusion injury. 639 65

If 60 min long ischemia of a liver tissue lobe occurred after feeding of rats with oil emulsion of alpha-tocopherol at a dose of 50 mg/kg within 12 hrs during 2 days, the "ischemic" decrease in metabolism of amidopyrine and aniline, in content of cytochrome P-450 and activity of initial and middle steps of NADPH-dependent redox chain as well as intensification of ascorbate-dependent peroxidation of membrane lipids were prevented in endoplasmic reticulum of hepatocytes. The protective effect of alpha-tocopherol on these xenobiotics metabolism is apparently related to an increase in catalytic activity of cytochrome P-450, to the enzyme antioxidant and membrane-stabilizing properties.
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PMID:[Effect of alpha-tocopherol on the hydroxylating system and lipid peroxidation in membranes of endoplasmic reticulum from ischemic rat liver]. 683 66

Tissue contents of NADPH and NADP+ were measured in freeze-clamped samples of normal rat liver and in four transplantable rat hepatomas covering a wide range of growth rates. Lowry cycling procedures were employed for analysis, using alkaline extracts for NADPH and acid extracts for NADP+. The mean NADPH content in 33 normal livers was 515 nmol/g wet weight, and mean NADP+ content was 311 nmol/g wet weight. In the four hepatomas, the amounts of both NADPH and NADP+ were low, and the extent of decrease correlated with tumor growth rate. In the slowly growing hepatoma 9618A, total NADP was slightly decreased (63% control) and more extensive decreases were observed in the medium growth rate tumors 47C and 8999 (38% and 19%, respectively, of control). In the rapidly growing hepatoma 3924A, total NADP was drastically decreased to 3% of the control liver value. Measurement of NADPH and NADP+ recovery from extracts of hepatoma 3924A showed that there were no inhibitors that might have blocked the activity of the assay enzymes. The NADPH/NADP+ ratio was close to the normal liver value in all four hepatomas. A 30-sec period of ischemia did not cause significant change in NADPH, but gave 33% decrease in liver NADP+. A 5-min period of ischemia decreased NADP+ to 50% of the zero-time value in liver, and to 71% in hepatoma 3924A, but was without effect on NADPH.
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PMID:Decreased content of reduced and oxidized nicotinamide-adenine dinucleotide phosphate in rat hepatomas. 715 Oct 32

In the hippocampus, ten minutes of transient global ischemia results in the death of CA1 pyramidal cells after a period of one to three days. The neurons in the CA1 region constitutively express NADPH-D (NADPH diaphorase activity). In contrast, astrocytes in the hippocampus do not normally express NADPH-D; but a population of reactive astrocytes (GFAP+ cells) begin to express of NADPH-D one day after transient global ischemia. NADPH-D is thought to be a histological marker for Nitric Oxide Synthase (NOS), the enzyme that is responsible for the synthesis of NO, a potent neurotoxin. We suggest that this increase in NADPH-D/NOS expression is an important element in the sequence of changes that occurs after ischemia, and that NO derived from reactive astrocytes or from neurons may play a causal role in neural cell death after ischemia in the hippocampus.
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PMID:Reactive astrocytes express NADPH diaphorase in vivo after transient ischemia. 768 11

The effects of dietary supplementation with eicosapentaenoic acid (EPA) on ventricular arrhythmias during myocardial infarction were examined in a canine model. EPA was incorporated into cellular membranes after ingestion of EPA-ester (100 mg/kg body weight/day) for 8 weeks. The ratio of EPA to arachidonic acid (AA) in platelet cell membranes and myocardial microsomes was significantly increased (7% to 37% in platelet cell membranes; p < 0.01, 3% to 12% in non-infarcted cardiac microsomes; p < 0.01, and from 2% to 8% in infarcted cardiac microsomes; p < 0.01). Dietary supplementation with EPA significantly reduced the incidence and severity of arrhythmias during coronary artery occlusion. Immediately after coronary artery occlusion, all of the animals in the control group that were given a toxic dose of digitalis developed ventricular tachycardia (VT) or ventricular fibrillation (Vf), whereas none of the animals in the EPA-supplement group developed VT or Vf within 15 min after administration of digitalis. Regardless of the presence of an infarcted area, the specific activity of the Ca(2+)-pump enzyme ((Ca(2+)-Mg2+)-ATPase) within the myocardial microsomal fraction of the EPA-supplemented group was significantly higher than in that of the control group (Vmax: 140.5 +/- 19.1 vs 94.8 +/- 28.9 nmol/mg/min in non-infarcted cardiac microsomes, p < 0.01, 130.9 +/- 18.4 vs 90.2 +/- 26.4 nmol/mg/min in infarcted cardiac microsomes, p < 0.01, EPA vs control group, respectively). The specific activities of the Na(+)-pump enzyme ((Na(+)-K+)-ATPase) and NADPH-dependent cytochrome C reductase in infarcted and non-infarcted cardiac microsomes did not differ between these groups. These results indicate that EPA supplementation increases the (Ca(2+)-Mg2+)-ATPase activity within myocardial membranes that is involved in Ca2+ metabolism in myocardial cells by increasing the ratio of EPA to AA within cellular membranes. These cellular alterations are likely to reduce the severity of ventricular arrhythmias by inhibiting the rapid accumulation of intracellular Ca2+ following ischemia.
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PMID:Antiarrhythmic effects of eicosapentaenoic acid during myocardial infarction--enhanced cardiac microsomal (Ca(2+)-Mg2+)-ATPase activity. 769 37

The role of the glutathione redox cycle in cellular protection form skin necrosis during the ischemic stress response (preconditioning) is unknown. In this series of experiments, we tested the hypothesis that oxidant stress reduces available total glutathione during injury and contributes to skin necrosis in flaps. Dorsal skin flaps (10 x 4 cm) were raised as acute flaps and skin grafts were obtained from the flaps at 0, 1, 4, 6, 12, or 24 hr. Some flaps were preconditioned as bipedicle flaps for 24, 48, 72, or 96 hr and the distal attachment divided before skin grafts were obtained 24 hr later. Flap survival was measured at 7 days. Total glutathione (GSH) and oxidized GSH (GSSG) were extracted and their levels determined enzymatically. Tissue GSH reductase (GR) activity was assayed with a spectrofluorometer and expressed as mumoles of NADPH oxidized/hr/g. Biochemical data were compared between the proximal and distal ends of the flaps using a two-tailed Student t test while differences between groups were compared using ANOVA. Skin necrosis was 5.4 +/- 0.12 cm in the distal ends at 7 days in acute flaps, while there was no skin necrosis in flaps preconditioned for 7 days. In acute flaps, total GSH levels fell precipitously in the distal end at 24 hr (P < 0.05). However, after 72 hr of preconditioning, the GSH levels in the distal end of the flap remained elevated while GSSG levels were undetectable. At 24 hr of ischemia, GR activity was 79 +/- 4 in the distal ends of acute flaps, while after preconditioning and 24 hr of ischemia, the GR activity increased to 172 +/- 13 in the distal ends (P < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Oxidant stress: the role of the glutathione redox cycle in skin preconditioning. 772 18

1. We investigated the effect of efonidipine hydrochloride (NZ-105) against acute renal failure (ARF) in male Wistar rats. ARF was produced by ischemia or glycerol. 2. Ischemia-induced ARF was produced by right nephrectomy and clamping of the left renal artery for 60 min, followed by reperfusion. NZ-105 (20 mg/kg) was orally administered twice a day for 3 days before ARF. The plasma creatinine and urea nitrogen concentrations were markedly elevated in the ischemia ARF group on the 1st day, but the elevation was significantly suppressed by NZ-105 treatment. 3. Glycerol-induced ARF was produced by intramuscular injection of 50% (v/v) glycerol (10 ml/kg) in rats which were restricted to drinking water for 24 hr. NZ-105 (20 mg/kg) was orally administered twice a day for 3 days before ARF. NZ-105 significantly attenuated the severe impairment of creatinine and urea nitrogen clearances and the elevated fractional sodium excretion (FENa) caused by ARF. 4. In the kidney homogenate, NZ-105 (10(-6)-10(-4) M) inhibited lipid peroxidation induced by ascorbic acid and Fe or by NADPH and the inhibitory effect of NZ-105 was stronger than alpha-tocopherol, an antioxidant agent. NZ-105 (10(-5)-10(-3) M) showed radical scavenging action against diphenyl-p-picrylhydrazyl and galvinoxyl induced radicals. 5. These findings suggest that NZ-105 prevents the renal damage caused by the two kinds of ARF. Moreover, the inhibitory effects of NZ-105 against lipid peroxidation and radical formation may be one of the mechanisms involved in the prevention of ARF.
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PMID:Effects of efonidipine hydrochloride (NZ-105), a new calcium antagonist, against acute renal failure in rats. 789 60

To evaluate the pathogenesis of lipid peroxidation in skin-flap necrosis and to select a novel herbal antioxidant to suppress lipid peroxidation and salvage the flaps, in vitro and in vivo experiments were instituted. In vitro studies revealed (1) the potentiality of the cutaneous microsomal system (vesicular fragment of endoplasmic reticulum) to generate oxyradicals by FeCl3 (oxidative agent), since NADPH-dependent lipid peroxidation was elevated time-dependently, (2) suppression of microsomal lipid peroxidation by herbal antioxidants (dose- and time-dependently), further supporting the theory of oxyradical-induced lipid peroxidation in the skin, and (3) that ellagic acid showed the strongest response, with curcumin, chlorogenic acid, and alpha-tocopherol (tocopherol) being moderate, and ferulic acid and gallic acid remaining weakest. Thus ellagic acid, curcumin, chlorogenic acid, and tocopherol at doses of 10, 60, 80 and 100 microM (twice I50, the dose which could inhibit lipid peroxidation by 50 percent) were chosen for in vivo assessments, respectively. In vivo studies were performed using rat back skin random flaps (70 x 15 mm and based anteriorly) and circular island flaps (20 mm in diameter and raised on superficial epigastric vessels). Control flaps were painted with a Tris-ethanol solution, and test flaps were painted with either ellagic acid, curcumin, chlorogenic acid, or tocopherol (above-mentioned doses per 250 microliters of Tris-ethanol per 300 mm2 of flap surface 1 hour before the operation and once a day for 3 postoperative days). Doses, frequency, and period of drug application were based on in vitro and in vivo pilot experiments. The results were as follows: (1) a direct and time-dependent relation was noticed between lipid peroxide levels and the rate of necrosis in both types of flap; (2) time-dependent elevation of lipid peroxide levels of skin, subcutaneous fat, and exudate of island flaps during ischemia and those of skin and subdermal fat after reperfusion indicated pre- and post-reflow states of lipid peroxidation rather than the original conception of merely reperfusion state; and (3) in good agreement with the results of in vitro experiments, ellagic acid exerted the strongest effect to suppress lipid peroxide levels of skin and to augment the viability of random flaps more than that of island flaps.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Involvement of lipid peroxidation in necrosis of skin flaps and its suppression by ellagic acid. 797 56

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