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

The effect of hyperoxia (1-14 days, 85% O2) on rat alveolar macrophage and alveolar type II cell oxidant and antioxidant characteristics was investigated. Unstimulated control macrophages (2 h ex vivo) released hydrogen peroxide at a rate of 3.5 +/- 1.3 nmol/min mg protein-1, which was a cyanide-sensitive process. H2O2 release from alveolar macrophages decreased slightly but not significantly after 1 day in hyperoxia and increased significantly after 3 days (180%, p less than .05) and 14 days (380%, p less than .01). When H2O2 release was expressed as nmol from total macrophages per animal, the increase after 14 days in hyperoxia was 760%. H2O2 generation by hyperoxic macrophages was cyanide resistant, indicating the involvement of active NADPH oxidase. In both control and hyperoxic macrophages H2O2 release could be significantly stimulated with phorbol myristate acetate (PMA). Comparisons of H2O2 release by freshly isolated alveolar macrophages and alveolar type II cells must be cautiously interpreted because some cell functions may change during the isolation procedure. Freshly isolated (6 h ex vivo) control alveolar type II cells were found to generate H2O2 at a rate of 0.26 +/- 0.05 nmol/min mg protein-1. In type II cells H2O2 release, calculated as nmol/mg protein, decreased during the first 7 days of hyperoxia to 10% (p less than .01) of the control value and then returned back up to the control level after 14 days. A similar decrease was observed if H2O2 release was calculated as nmol/cell number. H2O2 release from control and hyperoxic type II cells was cyanide sensitive. The decrease in H2O2 release in type II cells was associated with cell membrane injury (as assessed by electron microscopy), while biochemical markers of cellular injury (trypan blue exclusion and cellular high-energy phosphates ATP, ADP) were unchanged. The ability of type II cells to scavenge extracellular H2O2 did not change in acute hyperoxia, but it increased significantly during the second week in hyperoxia. These results indicate that macrophages but not type II cells are stimulated to produce H2O2 during prolonged exposure to hyperoxia.
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PMID:Hydrogen peroxide release from alveolar macrophages and alveolar type II cells during adaptation to hyperoxia in vivo. 139 11

Previous work has shown that irrespective of the route of exposure methyl isocyanate (MIC) caused acute lactic acidosis in rats (Jeevaratnam et al., Arch. Environ. Contam. Toxicol. 19, 314-319, 1990) and the hypoxia was of stagnant type due to tissue hypoperfusion resulting from hypovolemic hypotension in rabbits administered MIC subcutaneously (Jeevarathinam et al., Toxicology 51, 223-240, 1988). The present study was designed to investigate whether MIC could induce histotoxic hyperoxia through its effects on mitochondrial respiration. Male Wistar rats were used for liver mitochondrial and submitochondrial particle (SMP) preparation. Addition of MIC to tightly coupled mitochondria in vitro resulted in stimulation of state 4 respiration, abolition of respiratory control, decrease in ADP/O ratio, and inhibition of state 3 oxidation. The oxidation of NAD(+)-linked substrates (glutamate + malate) was more sensitive (five- to sixfold) to the inhibitory action of MIC than succinate while cytochrome oxidase remained unaffected. MIC induced twofold delay in the onset of anerobiosis, and cytochrome b reduction in SMP with NADH in vitro confirms inhibition of electron transport at complex I region. MIC also stimulated the ATPase activity in tightly coupled mitochondria while lipid peroxidation remained unaffected. As its hydrolysis products, methylamine and N,N'-dimethylurea failed to elicit any change in vitro; these effects reveal that MIC per se acts as an inhibitor of electron transport and a weak uncoupler. Administration of MIC sc at lethal dose caused a similar change only with NAD(+)-linked substrates, reflecting impairment of mitochondrial respiration at complex I region and thereby induction of histotoxic hypoxia in vivo.
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PMID:In vitro and in vivo effect of methyl isocyanate on rat liver mitochondrial respiration. 147 Nov 48

A study was made of the blood and tissue oxygen regime in patients with vibratory disease (VD) induced by local vibration and of the importance of lipid peroxidation (LPO) in oxygenation disorders. Venous hyperoxia, a decrease of the arteriovenous difference according to oxygen, the percentage of oxygen utilization by tissues, shift of the acid-base balance towards metabolic acidosis were established, attesting to tissue hypoxia that increased with the gravity of VD. The importance of a steady activation of LPO and depression of the antioxidant system in the pathogenesis of hypoxia associated with VD was supported by the correlation analysis data on oxygen balance and LPO, the functional and metabolic characteristics of red blood cells (according to the viscosity of red blood cell suspension and the content in the cells of SH-groups, lipoproteins and histidine) and platelets (according to aggregation in response to ADP and thrombin) as well as by the level of blood serum fluorescence. The authors provide evidence for the use of antioxidants (a complex of alpha-tocopherol with ascorbic acid and methionine and calcium antagonists of the nifedipine group), giving a membranostabilizing effect, in multimodality treatment of patients afflicted with VD.
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PMID:[Cell-membrane aspects of the pathogenesis of hypoxia in vibration disease induced by local vibration]. 204 32

Mitochondrial energy coupling in the gerbil brain was characterized by the relationship between intracellular phosphocreatine (PCr)/inorganic phosphate (Pi), phosphorylation ratio, and the mitochondrial redox state in graded hypoxia. Phosphorus-nuclear magnetic resonance (NMR) spectra of the brain and whole head were taken by surface and saddle coil, respectively. The NADH level of the brain cortex was monitored by in vivo fluororeflectometry. The PCr and Pi of the head and brain did not change between 100 and 10% O2 inhalation. PCr progressively decreased and Pi progressively increased with 6 and 4% 0% inhalation in the head. The PCr/Pi of the brain decreased by 44% at 6% fraction of inhaled oxygen (FIO2) and 57% at 4% FIO2. The ATP level did not change during hypoxia. The calculated phosphorylation ratio of the brain ([PCr] Kck[H+]/[Cr][Pi]) = ([ATP]/[ADP][Pi]) was 4.1 X 10(4) M-1 in normoxia. Hypoxia of increasing severity induced increasing NAD reduction of the brain cortex with 17% NAD reduction at 10% FIO2 when there was no change in phosphorylation ratio. The phosphorylation ratio decreased, i.e., the mitochondria failed to maintain the energy level of the brain when the magnitude of the change in NAD reduction to hypoxia was half of the total redox change between hyperoxia and anoxia. These studies demonstrated the feasibility of combined 31P-NMR and NADH fluorometry measurements on brain in vivo. The observations show similarities between the responses of mitochondrial oxidative phosphorylation to hypoxia in vivo and in vitro.
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PMID:Correlated in vivo 31P-NMR and NADH fluorometric studies on gerbil brain in graded hypoxia and hyperoxia. 336 55

For almost 10 years, numerous studies have shown that the pulmonary endothelium is endowed with a certain number of metabolic properties related to the uptake and hydrolysis of circulating vasoactive substances. Noradrenaline, serotonin, adenosine and possible certain prostaglandins are transported in the endothelial cells, according to processes which have now been clearly defined, and are there metabolised. Other compounds, including peptides (bradykinin, angiotensin I), or nucleotides (ATP, ADP, AMP) are hydrolysed in contact with the plasma membrane of the endothelium, without penetrating within the cell. For certain substrates (serotonin, angiotensin I), the properties of the pulmonary endothelial cell may be extended to systemic endothelial cells. For other substances, there would appear to be a specificity of endothelial function according to the site. It would appear that the lung, by virtue of its richness in endothelial cells, is capable of influencing concentrations of the circulating substances and, as a result, vascular tone. The existence of delicate processes of the uptake of substances has also been used to test the integrity of the cellular function of the pulmonary endothelium under experimental pathological condition, such as hyperoxia. However, before such a technique, based upon measurement os extraction of amines or other substances from various parts of the pulmonary circulation could be applied clinically, a critical consideration must be undertaken of the multiple factors involved in these processes. The major problem lies in the difficulty of distinguishing between dysfunction of the endothelial cells or a decrease in their number.
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PMID:[Measurement of pulmonary endothelial function; its potential clinical value]. 611 Dec 67

We analyzed brain tissue in 139 rats for adenosine and its metabolites, inosine and hypoxanthine, during the initial 120 seconds of seizures induced by bicuculline. We also measured ATP, ADP, AMP, phosphocreatine (PCr), and lactate. We divided the rats into four groups by adjustment of their preictal arterial oxygen tension: group I, PaO2 > 200 mm Hg; group II PaO2 = 50 mm Hg; and group III: PaO2 = 100 mm Hg. We treated a fourth group whose PaO2 = 100 mm Hg with phentolamine to block the 44% rise in blood pressure which occurred with the onset of seizures. PaCO2 was maintained between 30 anf 40 mm Hg in all groups. Brain tissue was sampled rapidly after 0, 10, 20, 30, 60, and 120 seconds of seizures by the freeze-blow technique. With normoxia (PaO2 = 100 mm Hg) or hyperoxia (PaO2 > 200 mm Hg), adenosine increased within ten seconds of the onset of seizures and remained elevated even after 120 seconds. Elevations in inosine and hypoxanthine were delayed compared to the increases in adenosine. A reduction in PaO2 (50 mm Hg) or systemic blood pressure during seizures caused a further augmentation in the increase in brain adenosine levels. During the seizure period, transient changes in adenine nucleotides and energy charge were observed, but PCr remained depressed and lactate continued to rise. The rapid and sustained increase in cerebral adenosine levels, temporally paralleling the changes in cerebral blood flow, supports the role for adenosine in the regulation of cerebral blood flow.
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PMID:Changes in brain adenosine during bicuculline-induced seizures in rats. Effects of hypoxia and altered systemic blood pressure. 677 98

Breathing of 100% oxygen at ambient pressure causes disorders in mouse brain organic phosphate phosphocreatine (PC), ATP, ADP, and AMP. The fast increase in PC level attains a maximum augmentation of about 50% after 16-18 h of exposure with subsequent slight alterations between 18 and 50 h. The initial losses (a) in ATP amount to approximately 20% after 4 h; (b) in ADP, 32% after 6-8 h; and (c) in AMP, about 40% after 30 min and 50% after 50 h. contrary to the continual decrease in AMP, the ATP and ADP values exhibit a later increase to a constant level during the full time of exposure up to 50 h. The initial loss in adenosine nucleotides points to an intense effect of hyperoxia in nerve cell metabolism with subsequent attainment of a new adenylate equilibrium at lower concentrations. The increased but constant level of PC may be due to an inhibition of the oxygen sensitive SH-groups, which are an essential center in the creatine kinase. Although the absolute concentration of AMP is by far the lowest of the three nucleotides, the continual decrease in AMP is of considerable importance because of its direct response to ATP via adenylate kinase reaction.
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PMID:Brain energy metabolism in mice exposed to oxygen at 1 atmosphere absolute. 733 82

A new micromethod for the determination of sphingomyelin in samples suspended in aqueous solutions, and modified micromethods for determining phosphatidylcholine and phosphatidylglycerol were used to determine phosphatidylcholine and sphingomyelin (detection limits of 1.8 mumol/l), and phosphatidylglycerol (detection limit of 2.3 mumol/l) in lipid dispersions, membranes from sheep erythrocytes and platelets, and pulmonary surfactants from rats of different ages and rats maintained under normobaric hyperoxia for 2 days prior to their sacrifice. The procedures are easy to perform, accurate, require less sample than conventional methods and can also be applied directly to aqueous samples. Phospholipase C and sphingomyelinase were used to release phosphorylcholine from phosphatidylglycerol and sphingomyelin, respectively. The choline released from phosphorylcholine by alkaline phosphatase is reconverted to phosphorylcholine by ATP and choline kinase. In the phophatidylglycerol determination, phospholipase D was used to release glycerol and phosphatidate. The glycerol formed was converted to glycerolphosphate using ATP and glycerol kinase. In all cases, the ADP thus formed was determined by following the enzymatic conversion of NADH to NAD at 340 nm in an coupled pyruvate kinase/lactate dehydrogenase system. Significant variations in the phospholipid composition of rat pulmonary surfactant were found during development; in particular there was an increase in the phosphatidylglycerol content of adult rats as compared with younger rats. Hyperoxia produced changes in the phosphatidylglycerol content of surfactant from adult rats, but not from 2-day old rats.
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PMID:Enzymatic determination of phosphatidylcholine, sphingomyelin and phosphatidylglycerol in lipid dispersions, blood cell membranes and rat pulmonary surfactant. 870 43

Sublethal exposure to hyperoxia in vivo induces oxidative damage that leads to destruction of the pulmonary endothelium, pleural effusion, and eventual pulmonary fibrosis. DNA is a potential target for reactive oxygen species in this system; the principle types of damage to DNA during hyperoxia are single-strand breaks and oxidant damage to bases. Poly(ADP-ribosyl)ation, a posttranslational modification of nuclear proteins, is stimulated by strand breaks in DNA and is required for effective repair of many types of DNA lesions. In this study we have measured lung tissue NAD+ and poly(ADP-ribose) concentrations in response to hyperoxia and niacin deficiency in rats. Male weaning Fischer-344 rats consumed niacin-deficient (ND) or niacin-replete pair-fed (PF) diets for 7 d. Rats from each diet group (n = 6) were then housed in normobaric 85% oxygen for 5 d. Normoxic controls were maintained in air. Hyperoxia increased lung poly(ADP-ribose) concentration by 35% in PF rats, but did not significantly increase levels in ND rats. Niacin deficiency decreased lung NAD+ in normoxic rats, but surprisingly, this deficit was partially reversed by hyperoxia. Liver NAD+ levels increased by 21% during hyperoxia in both diet groups. Heart and kidney NAD+ were unaffected by hyperoxia. Blood was the only tissue measured in which NAD+ was decreased by hyperoxia. Dietary treatment did not affect the increase in the lung wt/b. wt. ratio resulting from hyperoxia. This is the first report in the literature of lung tissue poly(ADP-ribose) measurement. Results show that hyperoxia causes a marked increase in lung poly (ADP-ribose) concentration, but also suggest an adaptation of whole-animal NAD+ metabolism to hyperoxia during niacin deficiency.
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PMID:Lung poly(ADP-ribose) and NAD+ concentrations during hyperoxia and niacin deficiency in the Fischer-344 rat. 872 36

We hypothesized that manganese superoxide dismutase (MnSOD), known to be induced in rat mesothelial cells by asbestos fibers, cytokines, and hyperoxia, may also be induced in asbestos-related pleural diseases such as mesothelioma. MnSOD was assessed in healthy human pleural mesothelium (n = 6), in biopsy samples of human pleural mesothelioma (n = 7), in transformed nonmalignant human mesothelial cells (Met5A), and in two human mesothelioma cell lines (M14K and M38K) established from the tumor tissue of mesothelioma patients. There was no MnSOD immunoreactivity in five of the six samples of healthy pleural mesothelium, whereas MnSOD immunoreactivity was high in the tumor cells in all the mesothelioma samples. Northern blotting, immunohistochemistry, Western blotting, and specific activity measurements showed lower MnSOD in the nonmalignant Met5A mesothelial cells than in the M14K and M38K mesothelioma cells. In additional experiments the mesothelial and mesothelioma cells were exposed to menadione, which generates superoxide intracellularly, and to epirubicin, a cytotoxic drug commonly used to treat mesothelioma. The M38K mesothelioma cells were most resistant to menadione and epirubicin when assessed by LDH release or by adenine nucleotide (ATP, ADP, and AMP) depletion. These same cells showed not only the highest MnSOD levels, but also the highest mRNA levels and activities of catalase, whereas glutathione peroxidase and glutathione reductase levels did not differ significantly. We conclude that MnSOD expression is low in healthy human pleural mesothelium and high in human malignant mesothelioma. The most resistant mesothelioma cells contained coordinated induction of MnSOD and catalase.
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PMID:Manganese superoxide dismutase in healthy human pleural mesothelium and in malignant pleural mesothelioma. 953 46


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