UMLS:C0242706 - FACTA Search

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Query: UMLS:C0242706 (hyperoxia)
5,219 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We hypothesised that reducing arterial oxyhaemoglobin (O2Hba) with carbon monoxide (CO) in both normoxia and hyperoxia, or acute hypoxia would cause similar compensatory increases in human skeletal muscle blood flow and vascular conductance during submaximal exercise, despite vast differences in arterial free oxygen partial pressure (Pa,O2). Seven healthy males completed four 5 min one-legged knee-extensor exercise bouts in the semi-supine position (30 +/- 3 W, mean +/- S.E.M.), separated by approximately 1 h of rest, under the following conditions: (a) normoxia (O2Hba = 195 ml l-1; Pa,O2 = 105 mmHg); (b) hypoxia (163 ml l-1; 47 mmHg); (c) CO + normoxia (18% COHba; 159 ml l-1; 119 mmHg); and (d) CO + hyperoxia (19% COHba; 158 ml l-1; 538 mmHg). CO + normoxia, CO + hyperoxia and systemic hypoxia resulted in a 29-44% higher leg blood flow and leg vascular conductance compared to normoxia (P < 0.05), without altering blood pH, blood acid-base balance or net leg lactate release. Leg blood flow and leg vascular conductance increased in association with reduced O2Hba (r2 = 0.92-0.95; P < 0.05), yet were unrelated to altered Pa,O2. This association was further substantiated in two subsequent studies with graded increases in COHba (n = 4) and NO synthase blockade (n = 2) in the presence of normal Pa,O2. The elevated leg blood flow with CO + normoxia and CO + hyperoxia allowed a approximately 17% greater O2 delivery (P < 0.05) to exercising muscles, compensating for the lower leg O2 extraction (61%) compared to normoxia and hypoxia (69%; P < 0.05), and thereby maintaining leg oxygen uptake constant. The compensatory increases in skeletal muscle blood flow and vascular conductance during exercise with both a CO load and systemic hypoxia are independent of pronounced alterations in Pa,O2 (47-538 mmHg), but are closely associated with reductions in O2Hba. These results suggest a pivotal role of O2 bound to haemoglobin in increasing skeletal muscle vasodilatation during exercise in humans.
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PMID:Exercising skeletal muscle blood flow in humans responds to reduction in arterial oxyhaemoglobin, but not to altered free oxygen. 1120 80

The objective of this study was to determine whether endogenous nitric oxide (NO), specifically the inducible NO synthase isoform (iNOS: NOS II), reduces or amplifies lung injury in mice breathing at a high oxygen tension. Previous studies have shown that exogenous (inhaled) NO protects against hyperoxia-induced lung injury, and that endogenous NO derived from iNOS inhibits leukocyte recruitment and protects against lung injury induced by lipopolysaccharide. In the present study, hyperoxia (> 98% O(2) for 72 h) induced acute lung injury in both wild-type and iNOS-deficient mice as determined by elevated albumin and lactate dehydrogenase levels in bronchoalveolar lavage fluid (BALF) and by increased extravascular lung water. Lung injury was greater in iNOS-deficient mice than in wild-type mice and was associated with an increased number of polymorphonuclear leukocytes in BALF. iNOS messenger RNA expression levels increased in the lungs of wild-type hyperoxic mice. Nitrotyrosine, a marker of reactive NO species, was expressed in both wild-type and iNOS-deficient mice in hyperoxia, indicating an iNOS-independent pathway for protein nitration. We conclude that iNOS is capable of reducing pulmonary leukocyte accumulation and lung injury. The data indicate that iNOS induction serves as a protective mechanism to minimize the effects of acute exposure to hyperoxia.
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PMID:Antiinflammatory properties of inducible nitric oxide synthase in acute hyperoxic lung injury. 1130 31

The extent to which endogenously generated nitric oxide alters Na(+) transport across the mammalian alveolar epithelium in vivo has not been documented. Herein we measured alveolar fluid clearance and nasal potential differences in mice lacking the inducible form of nitric oxide synthase [iNOS; iNOS(-/-)] and their corresponding wild-type controls [iNOS(+/+)]. Alveolar fluid clearance values in iNOS(+/+) and iNOS(-/-) anesthetized mice with normal oxygenation and acid-base balance were ~30% of instilled fluid/30 min. In both groups of mice, fluid absorption was dependent on vectorial Na(+) movement. Amiloride (1.5 mM) decreased alveolar fluid clearance in iNOS(+/+) mice by 61%, whereas forskolin (50 microM) increased alveolar fluid clearance by 55% by stimulating amiloride-insensitive pathways. Neither agent altered alveolar fluid clearance in iNOS(-/-) mice. Hyperoxia upregulated iNOS expression in iNOS(+/+) mice and decreased their amiloride-sensitive component of alveolar fluid clearance but had no effect on the corresponding values in iNOS(-/-) mice. Nasal potential difference measurements were consistent with alveolar fluid clearance in that both groups of mice had similar baseline values, which were amiloride sensitive in the iNOS(+/+) but not in the iNOS(-/-) mice. These data suggest that nitric oxide produced by iNOS under basal conditions plays an important role in regulating amiloride-sensitive Na(+) channels in alveolar and airway epithelia.
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PMID:Lack of amiloride-sensitive transport across alveolar and respiratory epithelium of iNOS(-/-) mice in vivo. 1150 1

Hyperoxia reduces the hemodynamic latency and enhances the response magnitude of the evoked local cerebral blood flow (LCBF). The objective of this study was to test the hypothesis that a change in the production of nitric oxide (NO) is involved in a unique change in evoked LCBF during hyperoxia. We measured LCBF in alpha-chloralose-anesthetized rats by laser-Doppler flowmetry. Systemic administration of the NO synthase inhibitor N(omega)-nitro-L-arginine (LNA) caused a decline in the baseline level of LCBF (P<0.01). The LNA intravenous injection during hyperoxia (hyperoxia with LNA) reduced the normalized evoked LCBF (normalization with respect to the baseline level of LCBF) in response to somatosensory stimulation by approximately 37% when compared under normal conditions (normoxia without LNA) (P<0.01), although that during normoxia (normoxia with LNA) did not cause a significant difference in the normalized evoked LCBF. The integrated neuronal activity under hyperoxia with LNA was approximately 11% lower than that under normoxia without LNA (P<0.05), although there was no significant difference in integrated neuronal activity between normoxia with LNA and normoxia without LNA. These results do not support our hypothesis and suggest the existence of another interaction mechanism involving oxygen for the enhancement of evoked LCBF under hyperoxia.
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PMID:Effect of nitric oxide synthase inhibitor on the local cerebral blood flow evoked by rat somatosensory stimulation under hyperoxia. 1181 16

The purpose of this investigation was to determine the impact of elevated partial pressures of O(2) on the steady state concentration of nitric oxide ((*)NO) in the cerebral cortex. Rodents with implanted O(2)- and (*)NO-specific microelectrodes were exposed to O(2) at partial pressures from 0.2 to 2.8 atmospheres absolute (ATA) for up to 45 min. Elevations in (*)NO concentration occurred with all partial pressures above that of ambient air. In rats exposed to 2.8 ATA O(2) the increase was 692 +/- 73 nM (S.E., n = 5) over control. Changes were not associated with alterations in concentrations of nitric oxide synthase (NOS) enzymes. Based on studies with knock-out mice lacking genes for neuronal NOS (nNOS) or endothelial NOS (eNOS), nNOS activity contributed over 90% to total (*)NO elevation due to hyperoxia. Immunoprecipitation studies indicated that hyperoxia doubles the amount of nNOS associated with the molecular chaperone, heat shock protein 90 (Hsp90). Both (*)NO elevations and the association between nNOS and Hsp90 were inhibited in rats infused with superoxide dismutase. Elevations of (*)NO were also inhibited by treatment with the relatively specific nNOS inhibitor, 7 nitroindazole, by the ansamycin antibiotics herbimycin and geldanamycin, by the antioxidant N-acetylcysteine, by the calcium channel blocker nimodipine, and by the N-methyl-D-aspartate inhibitor, MK 801. Hyperoxia did not alter eNOS association with Hsp90, nor did it modify nNOS or eNOS associations with calmodulin, the magnitude of eNOS tyrosine phosphorylation, or nNOS phosphorylation via calmodulin kinase. Cerebral cortex blood flow, measured by laser Doppler flow probe, increased during hyperoxia and may be causally related to elevations of steady state (*)NO concentration. We conclude that hyperoxia causes an increase in (*)NO synthesis as part of a response to oxidative stress. Mechanisms for nNOS activation include augmentation in the association with Hsp90 and intracellular entry of calcium.
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PMID:Stimulation of nitric oxide synthase in cerebral cortex due to elevated partial pressures of oxygen: an oxidative stress response. 1193 51

We have previously suggested that the spin trap agent, N-tert-butyl-alpha-phenylnitrone (PBN) can function not only as an antioxidant but also as a nitric oxide (NO) donor. To characterize the pharmacological activities of PBN against oxidative damage, we examined the effect of PBN on NO generation under hyperoxic conditions. The formation of NO in mice exposed to 95% oxygen was determined using a NOx analyzer and electron spin resonance (ESR). Levels of NOx, an oxidative product of NO, increased in the blood of mice under these conditions. However, the increase was returned to a normal level by the NOS (nitric oxide synthase) inhibitor, L-NMMA, indicating that the NO was formed via a biosynthetic pathway. In addition, ESR spectra of the liver and brain of control and experimental mice that were measured using Fe(DETC)2 as an NO trap reagent showed strong ESR signals from NO complexes in the livers of mice exposed to 95% oxygen. When examining the effect of PBN in mice, PBN reduced the NOx formation in the blood under the same hyperoxic conditions. In addition, the ESR intensity of the NO complex was weaker in the PBN-treated mice than in the non-treated mice, showing that PBN possess anti-inflammatory properties. However, under a normal atmosphere, NOx and ESR analyses showed that NO levels increased in PBN-treated mice but not in control mice. These findings suggested that PBN functions as an NO donor under specific physiological conditions. PBN appears to protect against hyperoxia-induced NO toxicity by anti-inflammatory action rather than by serving as an NO donor.
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PMID:Protective effect of spin trap agent, N-tert-butyl-alpha-phenylnitrone on hyperoxia-induced oxidative stress and its potential as a nitric oxide donor. 1199 81

The aim of this study was to evaluate the role of nitric oxide (NO) upon hyperbaric oxygen (HBO) toxicity in male Sprague-Dawley rats during exposure to 0.5 MPa >99% O(2). In the first experiment, the selective neuronal NO synthase inhibitor 7-nitroindazole (7-NI) was injected intraperitoneally (ip) in 15 rats. Another 15 rats received vehicle injections of peanut oil intraperitoneally. Latency to observable tonic-clonic convulsions and motor activity during the HBO exposure were scored and compared between the control group and the 7-NI group. The results showed that injection of 7-NI (30 mg/kg) significantly prolonged the latency to observable tonic-clonic convulsions. The 7-NI group also showed a significant decrease in motor activity compared with the control group. A second experiment was performed to measure the effect of 7-NI injections upon open-field activity during normobaric conditions. Twenty-four male Sprague-Dawley rats were randomly divided into three groups, each consisting of eight rats receiving 30 mg/kg 7-NI injections, 10 mg/kg 7-NI injections or vehicle injections of peanut oil intraperitoneally, respectively. The results showed that injection of 7-NI led to a significant dose-dependent reduction in horizontal and vertical activities. This study shows that 7-NI prolongs the latency to hyperoxia-induced seizures. However, it also demonstrates that 7-NI in doses ranging from 30 to 10 mg/kg has a secondary effect upon motor behavior in general. It can therefore not be ruled out that the protective effect of 7-NI upon HBO intoxication is partly due to reduced motor activity.
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PMID:Behavioral effects of 7-nitroindazole on hyperbaric oxygen toxicity. 1212

The aim of the present study was to compare microvessel responses to hypercapnic and isocapnic acidosis in hyperoxia-injured lungs and to assess the role of constitutive and inducible forms of nitric oxide synthase (NOS) and cyclo-oxygenase (COX). Real-time confocal luminescence microscopy was used to measure changes in the diameter of acinar arterioles, venules and capillaries in response to stimulation with hypercapnic and isocapnic acidosis in isolated rat lungs injured by 90% oxygen exposure for 48 h. Observations were made with and without inhibition of constitutive (endothelial constitutive NOS (ecNOS) and COX-1) and inducible isoforms (iNOS and COX-2) of NOS and COX. Upregulation of NOS was assessed by measuring enzyme levels in lung homogenates by Western blot analysis and enhancement of the COX-related pathway was judged from perfusate concentrations of 6-ketoprostaglandin F1alpha. ecNOS and COX-1, but not iNOS and COX-2, were upregulated in hyperoxia-injured lungs. The nitric oxide produced by ecNOS attenuated COX-1 activity in injured arterioles and venules, but carbon dioxide enhanced it, leading to paradoxical dilatation of these microvessels under hypercapnic conditions with ecNOS inhibition. Although a high hydrogen ion concentration was unnecessary for excitation of COX-1, venule constriction in response to H+ was enhanced by COX-1 inhibition. Constitutive, but not inducible, isoforms of cyclo-oxygenase and nitric oxide synthase play an important role in abnormal microvessel responses to carbon dioxide and hydrogen ions in hyperoxia-injured lungs.
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PMID:NOS and COX isoforms and abnormal microvessel responses to CO2 and H+ in hyperoxia-injured lungs. 1216 83

We hypothesized that elevated partial pressures of O(2) would increase perivascular nitric oxide (*NO) synthesis. Rodents with O(2)- and.NO-specific microelectrodes implanted adjacent to the abdominal aorta were exposed to O(2) at partial pressures from 0.2 to 2.8 atmospheres absolute (ATA). Exposures to 2.0 and 2.8 ATA O(2) stimulated neuronal (type I) NO synthase (nNOS) and significantly increased steady-state.NO concentration, but the mechanism for enzyme activation differed at each partial pressure. At both pressures, elevations in.NO concentration were inhibited by the nNOS inhibitor 7-nitroindazole and the calcium channel blocker nimodipine. Enzyme activation at 2.0 ATA O(2) appeared to be due to an altered cellular redox state. Exposure to 2.8 ATA O(2), but not 2.0 ATA O(2), increased nNOS activity by enhancing nNOS association with calmodulin, and an inhibitory effect of geldanamycin indicated that the association was facilitated by heat shock protein 90. Infusion of superoxide dismutase inhibited.NO elevation at 2.8 but not 2.0 ATA O(2). Hyperoxia increased the concentration of.NO associated with hemoglobin. These findings highlight the complexity of oxidative stress responses and may help explain some of the dose responses associated with therapeutic applications of hyperbaric oxygen.
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PMID:Stimulation of perivascular nitric oxide synthesis by oxygen. 1250 79

Hypoxia disturbs Ca(2+) regulation and increases the intracellular Ca(2+) concentration ([Ca(2+)](i)), which may in turn activate the nitric oxide synthase (NOS) regulated by [Ca(2+)](i). Since nitric oxide (NO) reduces the isometric contractility of rat diaphragm in vitro, we hypothesized that NO contributes to the impaired force generation of an hypoxic diaphragm. The effects of different concentrations of the NOS inhibitor, N(G)-monomethyl-L-arginine (L-NMMA), the NO scavenger haemoglobin (150 micro mol.l(-1)) and the NO donor spermine NONOate (Sp-NO; 1 mmol.l(-1)) were determined on isometric contractility during hypoxia [partial pressure of oxygen, PO(2), about 7 kPa (about 54 mmHg)] and hyperoxia [ PO(2) about 83 kPa (about 639 mmHg)]. Hypoxia significantly reduced maximal twitch force ( F(t)), and submaximal tetanic force (30 Hz, F(30)) in all L-NMMA groups. A low concentration of L-NMMA (30 micromol.l(-1)) increased F(30) but a high concentration (1,000 micromol.l(-1)) reduced F(30) during hypoxia. The effects of L-NMMA on force generation were more pronounced during hypoxia compared to hyperoxia. Peak increases in F(30) and F(t) were observed at a concentration of 30 micromol.l(-1) L-NMMA during hypoxia, but with 10 micromol.l(-1) L-NMMA during hyperoxia. The same concentration of haemoglobin increased F(30) and F(t) less during hypoxia compared to hyperoxia. The Sp-NO reduced F(t), F(30) and maximal tetanic force (F(0)) during hypoxia; these effects were abolished in the presence of haemoglobin. The Sp-NO did not alter F(t), F(30) and F(0)during hyperoxia. We conclude that NO plays a more prominent role during hypoxia and that NO contributes to the depression of force generation in the hypoxic rat diaphragm in vitro. This change may be related to an elevated NO generation within the hypoxic diaphragm.
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PMID:Role of nitric oxide in isometric contraction properties of rat diaphragm during hypoxia. 1252 72

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