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

While treatment with supplemental oxygen is often essential in patients with lung disease, prolonged therapy may cause lung injury by itself. Although the mechanisms responsible for initiating hyperoxic lung damage almost certainly involve primary oxidative transformations, the possible contributions of inflammation to the tissue injury have been attracting increasing research activity. Increases in intercellular adhesion molecule-1 (ICAM-1) coincide with the inflammation, but in other models of inflammation transient adhesion mediated by members of the Selectin gene family was found to be essential before ICAM-1/beta 2 interactions could occur. We, therefore, wondered whether a similar sequence of initial transient adhesion followed by subsequent responses would be observed in hyperoxic lung inflammation. We, therefore, determined the effects of hyperoxia exposure on lung mRNA for P- and E-Selectin in mouse lungs. We found that there was no detectable mRNA for E-Selectin through 72 h of hyperoxia exposure by Northern blotting, but that mRNA for P-Selectin was detectable as early as 48 h after initiation of hyperoxia. To determine the location of P-Selectin upregulation we examined hyperoxia-exposed mouse lungs by in situ hybridization and found that the upregulation of P-Selectin at 48 h was localized to large muscularized vessels, at 72 h expression was detected in some medium size muscularized vessels, and at 96 h abundant expression was observed also on nonmuscularized small vessels. In conclusion, increases in mRNA for P-Selectin early in the course of hyperoxia exposure suggest that P-Selectin expression in hyperoxic lungs increases in parallel with upregulation of ICAM-1, leading to the accumulation of neutrophils in hyperoxic lungs, and that interventions targeting these two adhesion molecules may lead to a diminution in hyperoxic lung inflammation and lung injury.
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PMID:P-selectin is upregulated early in the course of hyperoxic lung injury in mice. 888 9

The pulmonary damage caused by prolonged exposure to high oxygen concentrations is accompanied by lung inflammation, which may contribute to the expression of hyperoxic lung injury. In turn, adhesion molecules are crucial for initiating inflammatory responses. The goal of the present study was to investigate the association of contents of soluble adhesion molecules in plasma or alveolar fluids of hyperoxic rats with lung expression of adhesion molecules, lung inflammation and lung injury. We exposed adult Sprague-Dawley rats to > 95% oxygen for up to 60 h and measured the contents of intercellular adhesion molecule-I (ICAM-I) and E-Selectin in plasma and lung tissue expression of the same molecules, and we assessed lung myeloperoxidase (MPO) activties and lung water contents as indices of lung inflammation and injury, respectively. We also assessed ICAM-I content in lavage samples, because ICAM-I may be shed from the alveolar epithelium. Lung water was elevated at 60 h of hyperoxia-exposure, and this effect was preceded by increases in lung MPO activities. Lung ICAM-I expression was more than doubled at 48 h, although soluble ICAM-I contents were not elevated in plasma or lavage. Soluble E-Selectin was increased by more than 50% at 24 h of hyperoxia-exposure, while lung expressions of E-Selectin were not increased until 48 h. The sequence of the events observed in the present studies suggests that E-Selectin contributes to lung inflammation in hyperoxia and the acceleration of lung injury immediately following the inflammatory response suggests a pivotal role for inflammation in this injury.
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PMID:Increased soluble E-Selectin is associated with lung inflammation, and lung injury in hyperoxia-exposed rats. 891 24

Infants and adults on oxygen often are treated with glucocorticoids in an attempt to reduce lung inflammatory injury. However, glucocorticoids hasten the development of hyperoxic lung injury in some animal models. The purpose of this study was to test the hypothesis that dexamethasone alters the lung inflammatory responses to hyperoxia exposure. We studied male Sprague-Dawley rats, placing them in >95% oxygen immediately after administration of 0, 0.1, 1, or 10 mg/kg of dexamethasone. At 0, 24, or 48 hr of exposure to hyperoxia, extravascular lung water contents were measured, and lung inflammatory responses were assessed by lung myeloperoxidase activities, lung neutrophil counts, and lung expression of E-Selectin and intercellular adhesions molecule-1 (ICAM-1). Dexamethasone, independent of exposure to hyperoxia, led to marked increases in lung neutrophil counts, without increases in lung myeloperoxidase activities or increases in the expression of the adhesion molecules. Hyperoxia exposure also enhanced lung neutrophil accumulation, and extravascular lung water increased earlier in animals exposed to hyperoxia and dexamethasone than in those exposed to hyperoxia alone. In conclusion, the increase in lung neutrophils in dexamethasone-treated rats without enhanced expression of E-Selectin or intracellular adhesions molecule-1 suggests that dexamethasone leads to lung neutrophil accumulation by its effect on neutrophils. The more rapid development of hyperoxic lung injury associated with earlier lung neutrophil accumulation suggests that dexamethasone-induced lung neutrophil sequestration primes the lung for the development of hyperoxic lung injury and supports further the conclusion that lung inflammation contributes significantly to the development of hyperoxic lung injury.
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PMID:Dexamethasone enhancement of hyperoxic lung inflammation in rats independent of adhesion molecule expression. 969 81