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)

Bilirubin is a potent antioxidant in vitro. To determine whether bilirubin also is an antioxidant in vivo, we studied markers of oxidative injury in the Gunn rat model exposed to hyperoxia. Homozygous jaundiced males were mated with heterozygous nonjaundiced females to obtain both jaundiced and nonjaundiced pups within a litter. Once delivered, the pups and their mother were placed in air (21% O2) or hyperoxia (> 95% O2) for 3 d. Both jaundiced and nonjaundiced pups were removed from the chambers daily. Animals were sacrificed and blood was drawn for determination of serum bilirubin, blood thiobarbituric acid-reactive substances (TBARS) by fluorescence assay, serum hydroperoxides, and serum protein oxidation. Tissues (liver, lung, and brain) were assayed for lipid peroxides (TBARS, conjugated dienes [CD], loss of polyunsaturated fatty acid content [PUFA]). We also measured a wide range of serum antioxidants including superoxide dismutase, catalase, glutathione, vitamins A, C, and E, and uric acid. Blood TBARS were significantly decreased in the jaundiced pups compared to the nonjaundiced pups on day 3 of hyperoxia, and blood TBARS were inversely correlated to serum bilirubin on day 3 of hyperoxia (R2 +/- .89). Similar decreases in serum lipid hydroperoxides and serum protein carbonyl content were detected in the jaundiced pups as compared to their nonjaundiced littermates. Other serum antioxidants were not increased in jaundiced animals compared to nonjaundiced animals. Relative lung weight was lower in jaundiced pups exposed to hyperoxia compared to similarly exposed nonjaundiced pups, suggesting a reduction in hyperoxia-induced lung edema. We detected no significant effects of bilirubin on parameters of lipid peroxidation in solid tissues. We conclude that serum bilirubin protects against serum oxidative damage in the first days of life in neonatal Gunn rats exposed to hyperoxia. We speculate that bilirubin is a functionally important transitional antioxidant in the circulation of human neonates and that it may be involved in modulation of injury due to hyperoxia.
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PMID:Hyperbilirubinemia results in reduced oxidative injury in neonatal Gunn rats exposed to hyperoxia. 759 Mar 89

Although lethal exposures of most animal species to oxygen result in a reduced amount of surfactant phospholipids (PL), hyperoxia in rats leads to elevated levels of PL on the alveolar surface. Because of this different response, a study was made of the amount, composition, surface properties, and subfraction distribution (obtained by differential centrifugation) of alveolar lavage materials from rats exposed to > 95% oxygen for 64 h. The exposures lead to severe lung damage, which includes the appearance of pleural effusion, pulmonary edema, and increased protein levels on the alveolar surface. However, the PL levels of lavage fluid are increased two- to threefold, and the PL composition is altered. In O2-exposed rats, only 39(+/- 1)% of the phospholipid is disaturated phosphatidylcholine (DSPC), the major surface active component of surfactant, as compared to 46(+/- 1)% DSPC in lavage from control animals. The distribution of PL and DSPC in subfractions of lavage materials obtained by differential centrifugation is approximately reversed following hyperoxia. In lavage from control animals, 36% of the PL is in the heavier, more dense subfractions and 64% is in the lighter, less dense subfractions, while 72% is heavier and 28% lighter in lavage from O2-exposed animals. Measurements of surface properties with the Wilhelmy balance indicate that the ability of the lavage materials to reduce surface tension is impaired following hyperoxia. Thus, lethal exposures of rats to oxygen lead to increased amounts of surfactant on the alveolar surface, but the surface properties of the surfactant are impaired, probably due to reduced levels of DSPC, increased amounts of protein, and alterations in its physical form.
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PMID:Hyperoxia-induced alterations of rat alveolar lavage composition and properties. 772 73

The pathogenesis of pulmonary oxygen toxicity is postulated to be related in part to neutrophil-mediated injury. This study examined the effect of a monoclonal antibody directed against the CD11a,b,c/CD18 glycoprotein complex (beta 2 leukocyte integrins) on oxygen-induced lung injury. M8, a monoclonal antibody that binds to the beta chain of the guinea pig leukocyte integrins that facilitate neutrophil adherence to vascular endothelium, was injected into adult guinea pigs prior to and during exposure to > 98% oxygen. Control oxygen-exposed animals were injected with a noninhibitory antibody to the CD18 complex or with saline. Survival in oxygen was similar for animals treated with M8 when compared with those treated with saline (102 versus 105 h, respectively, NS). Pulmonary edema as assessed by protein in the supernatant of bronchoalveolar lavage fluid (BALF) was higher in the three groups of oxygen-exposed animals than in the air-exposed groups (p < 0.01), but it did not differ between the M8 antibody treatment group and the other oxygen-exposed groups. M8 antibody treatment did not decrease hyperoxia-induced neutrophil accumulation into the lung as assessed by myeloperoxidase activity (MPO) in lung homogenates or by neutrophil counts in histologic specimens. M8 antibody also did not decrease neutrophil counts or MPO in alveolar lavage fluid, both of which were significantly elevated in all oxygen-exposed groups. These results suggest that hyperoxia-induced neutrophil migration into the lung and acute lung injury occurs by CD18-independent processes in the guinea pig model of pulmonary oxygen toxicity.
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PMID:Oxygen-induced lung injury in the guinea pig proceeds through CD18-independent mechanisms. 790 67

Oxygen toxicity is attributed to the reaction of oxygen metabolites with cellular components leading to cell destruction. Activation of latent human neutrophil interstitial collagenase by reactive oxygen species has been demonstrated. The potential role of collagenases in hyperoxic lung injury has not been investigated. We studied the effect of hyperoxia on newborn rat lung water content, morphology and ultrastructure, interstitial (type I) and type IV collagenase gene expression and type I and IV collagenolytic activity. We observed that hyperoxia causes pulmonary edema, alters newborn rat lung morphology in a sequential manner and produces ultrastructural alterations, induces type I and increases type IV collagenase mRNA expression, and increases type I and IV collagenolytic activity. A role for type I and IV collagenase in hyperoxic newborn lung injury or in the recovery following the injury is proposed.
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PMID:Hyperoxia induces interstitial (type I) and increases type IV collagenase mRNA expression and increases type I and IV collagenolytic activity in newborn rat lung. 799 51

Surfactant dysfunction contributes to the pathophysiology of adult respiratory distress syndrome (ARDS), and we hypothesized that surfactant treatment would improve experimental ARDS produced by continuous exposure to hyperoxia. Twelve healthy male baboons (10-15 kg) were anesthetized, paralyzed, and mechanically ventilated with 2.5 cmH2O positive end-expiratory pressure (PEEP) for 96 h. Baboons were divided into three groups: 1) the O2 group (n = 5) received 100% O2, 2) the surfactant group (n = 5) received 100% O2 and aerosolized porcine surfactant, and 3) a control group (n = 2) was ventilated at fractional concentration of inspired O2 of 0.21 for 96 h to control for effects of anesthesia and mechanical ventilation. Hemodynamic parameters were obtained every 12 h, and ventilation-perfusion (VA/Q) distribution was measured daily by multiple inert gas elimination technique. PEEP was increased once or twice daily to 10 cmH2O for 30 min to study its effects on measurements of VA/Q. At the end of experiments, lungs were obtained for biochemical analysis. Prolonged hyperoxia resulted in progressive worsening in VA/Q, hemodynamic deterioration, severe lung edema, and altered surfactant metabolism. Surfactant administration increased disaturated phosphatidylcholine in lavage fluid but did not improve lung edema or gas exchange. In the surfactant group, however, the addition of 10 cmH2O PEEP resulted in a greater degree of shunt reduction than did 2.5 cmH2O PEEP (47 vs. 31% in the O2 group, P < 0.05). We conclude that aerosolized porcine surfactant did not prevent pulmonary O2 injury in baboons, but it potentiated the shunt-reducing effect of PEEP.
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PMID:Natural surfactant and hyperoxic lung injury in primates. I. Physiology and biochemistry. 800 91

Lymphatics are important in the resolution of pulmonary edema, but which lymphatics drain alveolar fluid and how they change during lung injury and edema is uncertain. To study this question 16 rats were exposed to 85% O2 for 7 days. At 0, 3, 7, and 14 days after removal from the hyperoxic chamber, the lungs of the rats were cast by instilling methyl methacrylate into the trachea. The lungs of four similar room-air breathing rats served as controls. Tissue was taken for light microscopy and the casts were examined for lymphatic filling with a scanning electron microscope. Rats exposed to hyperoxia had diffuse damage and extensive edema. On removal from hyperoxia (day 0), 29% of the rat bronchioles had saccular lymphatic casts around them and 6% of bronchioles were surrounded by these lymphatics. Twenty-five percent of bronchioles had conduit lymphatic casts. Fourteen percent of arteries had lymphatic casts around them. All were different from the rats kept in room air (P < 0.0001). Rats exposed to hyperoxia had lymphatics on the pleural surface, near alveoli and alveolar ducts, and around veins. The peribronchial and periarterial saccular lymphatics formed separate groups with communicating conduit lymphatics. The perivenous lymphatics had their own separate conduit lymphatics. Fourteen days after returning to ambient air, the lymphatics were similar to those of control animals. In this model, airway casting allows three-dimensional analysis of the lung lymphatics. It shows that lymphatic compartments expand during hyperoxic lung injury and that peribronchial and perivascular saccular lymphatics connect to conduit lymphatics of the bronchoalveolar bundle.
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PMID:Lung lymphatics cast from the airspace. 807 44

Oxygen therapy is administered to decrease tissue hypoxia and to relieve arterial hypoxemia. High concentrations of oxygen are often used in patients with adult respiratory distress syndrome. Supplying oxygen to animals has been known to produce tissue damage, with toxicity increasing with the increase of oxygen concentrations and exposure pressures. End-organ damage from hyperoxia depends on both the concentration of oxygen administered and the oxygen pressure during exposure. Prolonged exposure to hyperbaric oxygen causes central nervous system and pulmonary toxicity, which results in atelectasis, pulmonary edema, and seizures. Lung damage may occur as a result of normobaric hyperoxia. A severe retinopathy (retrolental fibroplasia) occurs in neonates during oxygen exposures. For all of these reasons, the lowest possible concentration of oxygen that relieves tissue hypoxia is recommended in patients with adult respiratory distress syndrome.
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PMID:Oxygen toxicity. 808 71

Lung injury caused by breathing enriched oxygen continues to be a major problem in clinical medicine. Experimentally, hyperoxic lung injury is characterized by pulmonary edema and associated neutrophil accumulation. Although extensively investigated, the mechanisms for neutrophil accumulation and the role of this accumulation in hyperoxic lung injury remain controversial. Intercellular adhesion molecule-1 (ICAM-1) is an adhesion molecule that when increased on endothelium by inflammatory cytokines leads to increased adhesion of neutrophils to the inflamed endothelium and transendothelial migration. The purpose of this study was to examine the role of inflammation in hyperoxia-induced lung injury by investigating ICAM-1 expression in the lungs of mice exposed to > 95% oxygen continuously. Lung tissue from mice exposed to > 95% oxygen was analyzed for ICAM-1 mRNA by slot blot analysis and for ICAM-1 protein expression. We also examined lungs from mice exposed to hyperoxia for up to 96 h by light microscopy to correlate pulmonary inflammation with ICAM-1 expression. We found that mRNA for ICAM-1 increased 56% over baseline after 48 h of exposure to hyperoxia, that ICAM-1 protein increased by more than 5-fold over baseline after 96 h of exposure to hyperoxia, and that lung inflammation and injury were not evident until 96 h of exposure. Our data demonstrate that exposure to hyperoxia causes an increase in ICAM-1 gene transcription and/or mRNA stability in mouse lungs, and that this increase is followed by an increase in ICAM-1 protein.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Increases in lung tissue expression of intercellular adhesion molecule-1 are associated with hyperoxic lung injury and inflammation in mice. 810 35

We investigated the effects of lung edema protein on ventilatory mechanics with special reference to surfactant activity. The edema fluid was obtained from hyperoxia-exposed adult rabbits. In immature newborn rabbits that could not be artificially ventilated at an insufflation pressure of 25 cm H2O, mean tidal volumes of > 27 ml/kg were obtained by supplementation with a natural surfactant (S-alone) or natural surfactant mixed with lung edema fluid (EF), the edema protein-to-surfactant ratio of which was < or = 5.6. A mixture with a ratio of 11.2 (11.2-EF/S), however, decreased the volume to 10.9 ml/kg (P < 0.05 vs S-alone). Surfactant mixed with isolated albumin at a concentration equal to that in 11.2-EF/S decreased the tidal volume to 8.6 ml/kg (NS vs 11.2-EF/S), and with isolated fibrinogen lowered it to 18.1 mg/kg (P < 0.05 vs S-alone). We conclude that lung edema fluid impairs ventilation through surfactant inactivation when the protein-to-surfactant ratio increases, and that albumin and fibrinogen are the main causes of this impairment.
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PMID:Impairment of surfactant activity and ventilation by proteins in lung edema fluid. 815 52

Because fetal rat lungs have lower baseline levels of both surfactant and antioxidant enzymes than full-term newborn rats, we questioned whether prematurely delivered rats might be more susceptible to O2 toxicity than those born at term. In the present studies, prematurely delivered rats (gestational d 21 of 22) and full-term rat pups were simultaneously put in > 95% O2 after birth. Surprisingly, we found that the preterm rats were not more susceptible to O2-induced lung damage and lethality than full-term newborns, but, in fact, the composite percentage of survival was even greater in the preterm pups from 7 to 9 d in hyperoxia and were similar thereafter up to 14 d in high O2. In addition, the preterm rats showed significantly decreased lung wet/dry weight ratios and consistently less severe pathologic evidence of pulmonary edema compared with term rats at 6 and 8 d of O2 exposure. The premature pups demonstrated the capability of inducing pulmonary antioxidant enzyme responses to hyperoxia by 3 d, and had significantly elevated copper-zinc superoxide dismutase, catalase, and glutathione peroxidase activities (and lung surfactant contents) at 6 d of O2 exposure compared with the term rats in O2. The rates of lung total O2 consumption and cyanide-resistant O2 consumption at d 6 in hyperoxia were not different for preterm versus term pups.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Comparative responses of premature versus full-term newborn rats to prolonged hyperoxia. 816 59

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