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)

Exposure to hyperoxia, especially under hyperbaric conditions, causes an enhanced oxidative stress particularly in lung tissue. To test the potential hazardous effect of either a single or repeated hyperbaric oxygen treatment (HBO) on the cellular defence system the glutathione status of lung tissue from rats exposed to HBO was investigated. When daily exposed to 2.5 ATA of > 95% O2 for 90 min over 8 or 14 days the content of reduced glutathione in lung tissue (GSH) increased by 16-19%. Oxidized glutathione (GSSG) tended to increase after 8 days and was 56% higher after 14 days. While the GSSG/GSH ratio was unchanged after 8 days, it increased by 39% after 14 days. Thus, the GSH increase after 8 days can be understood as a adaptive process to protect the lung from oxidative stress. The distinct increment of the cellular GSSG that lead to an increase of the GSSG/GSH ratio after 14 days reflects a situation, in which the cellular defence system is overwhelmed by oxidative stress. The additional pretreatment with perfluorochemicals in a dose of 2g/kg every second day aggravated the observed changes (GSH +39-19%, GSSG +118%). In a second experiment rats were exposed to a single session with 7 ATA of O2 for 60 min. GSH in the lungs increased for 40%, it was not elevated by PFC. However, GSSG increased to a much higher degree in untreated as well as in PFC-treated animals (+240%, +163%), elevating the ratio GSSG/GSH markedly (+145%, +176%). Allopurinol given as radical scavenger in a dose of 50 mg/kg was able to suppress the increased oxidative stress widely. Thus adaptive and overloading processes are involved under the treatment with increased oxygen pressures. As the administration of PFC aggravates the observed changes, a still increased blood oxygen offer must be considered as the causative agent. A radical scavenger is capable to suppress the increased oxidative stress widely.
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PMID:Effect of hyperbaric oxygen treatment and perfluorochemical administration on glutathione status of the lung. 128 20

To test the hypothesis that administration of allopurinol could modify the response to prolonged hyperoxia in premature baboons (140 days gestation) with respiratory distress syndrome, we evaluated physiological, pathological, and lung biochemical parameters in groups of premature baboons treated with mechanical ventilation and exposed to various amounts of oxygen for 6 days. Three groups of experimental animals were studied, including animals that received oxygen as needed to maintain arterial oxygen between 60 and 80 Torr [inspiratory O2 concentration- (FIO2) PRN], animals that received 100% oxygen continuously but also received allopurinol intravenously at a dose of 10 mg.kg-1.day-1 (FIO2-1.0 + allopurinol), and animals that received 100% oxygen continuously and the vehicle for allopurinol administration (FIO2-1.0). Pathological examinations of the experimental animals showed evidence of lung injury in both 100% oxygen-exposed groups, but the allopurinol-treated animals had findings more compatible with the FIO2-PRN group, with relatively few macrophages or polymorphonuclear lymphocytes being present in lung tissue. Lungs of animals treated with allopurinol were also more distensible and had a trend toward decreased lung water compared with the FIO2-1.0 group. Allopurinol-treated animals were able to induce lung glutathione concentrations and glutathione-related and antioxidant enzyme activities compared with the normoxic control (FIO2-PRN) group. Ventilator pressure requirements were also decreased in the allopurinol-treated animals compared with the FIO2-1.0 controls after 42 h. These data suggest that treatment of hyperoxia-exposed premature baboons with allopurinol for the first 6 days of life results in significant changes in lung responses and antioxidant defenses compared with vehicle-treated baboons exposed to 100% oxygen for the same time period.
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PMID:Allopurinol-induced effects in premature baboons with respiratory distress syndrome. 203 82

Neutrophil accumulation in alveolar spaces is a conspicuous finding in hyperoxia-exposed lungs. We hypothesized that xanthine oxidase (XO)-derived oxidants contribute to retention of neutrophils in hyperoxic lungs. Rats were subjected to normobaric hyperoxia (100% O2) for 48 h, and lungs were assessed for neutrophil sequestration (morphometry and lavage cell counts) and injury (lavage albumin levels and lung weights). In rats exposed to hyperoxia, we found increased (P < 0.05) lung neutrophil retention, lavage albumin levels, and lung weights compared with normoxia-exposed control rats. Suppression of XO activity by pretreatment with allopurinol decreased (P < 0.05) lung neutrophil retention but increased (P < 0.05) lavage albumin concentrations and lung weights in hyperoxic rats. Allopurinol treatment had no effect (P > 0.05) on the numbers of macrophages or lymphocytes recoverable by lung lavage. Depletion of XO activity by an independent method, tungsten feeding, also decreased (P < 0.05) lung lavage neutrophil counts and increased (P < 0.05) lavage albumin concentrations. We conclude that XO may be involved in lung neutrophil retention but not lung injury during exposure to hyperoxia.
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PMID:Xanthine oxidase promotes neutrophil sequestration but not injury in hyperoxic lungs. 817 9

Recent evidence indicates that hypoxia enhances the generation of oxidants. Little is known about the role of free radicals in contractility of the rat diaphragm during hypoxia. We hypothesized that antioxidants improve contractility of the hypoxic rat diaphragm and that xanthine oxidase (XO) is an important source of free radicals in the hypoxic diaphragm. The effects of N-acetylcysteine (NAC; 18 mM), Tiron (10 mM), and the XO inhibitor allopurinol (250 microM) were studied on isometric and isotonic force generation during hypoxia (PO(2) approximately 7 kPa). NAC and Tiron decreased maximal force generation, slowed the shortening velocity, and decreased the power output. Fatigue rate was decreased in the presence of either NAC or Tiron. Allopurinol did not alter the contractility or fatigability of the diaphragm. During hyperoxia (PO(2) approximately 85 kPa), neither NAC nor allopurinol affected the contractility or fatigability of the diaphragm. Thus free radicals play a significant role in diaphragm contractility during hypoxia. Whether antioxidants exert a beneficial or harmful effect on muscle performance depends on the contraction pattern of the muscle. Free radicals generated by XO do not play a role in diaphragm contractility during either hypoxia or hyperoxia.
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PMID:Free radicals in hypoxic rat diaphragm contractility: no role for xanthine oxidase. 1170 36