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

Prolonged exposure to hyperoxia markedly inhibits normal lung development (alveolarization and respiratory surface area expansion) in immature animals. Since (a) hyperoxia results in excess hydroxyl radical (OH.) formation, (b) (OH.) is implicated in O2-induced lipid peroxidation and DNA alterations, and (c) both OH. formation and its interaction with DNA are Fe++ dependent; chelation of Fe++ should act to protect against pulmonary O2 toxicity and hyperoxic inhibition of lung development. We therefore treated litters of newborn rats with the iron chelator Deferoxamine mesylate (DES) (150 mg/kg/day) during a 10-day exposure to greater than 95% O2. Morphometric analysis demonstrated that compared to the mean airspace size in air control rat pups (Lm = 44.5 microns), hyperoxic exposure resulted in a 34% larger mean air space diameter in O2-saline rat lungs (59.5 microns) versus only an 11% enlargement in O2-DES lungs (51.1 microns*). Lung internal surface area (cm2) per 100-g body weight were air control = 4480, O2-saline = 3570 (decreases 20.3%), and O2-DES = 4125* (decreases 7.9%) (*p less than 0.05 versus O2-saline group). DES-treated animals also had significantly decreased lung conjugated diene levels during hyperoxic exposure and increased lung elastin content (reflective of preserved lung alveolar formation) compared to O2-saline rats. These results indicate that DES treatment substantially ameliorated the inhibitory effects of neonatal hyperoxic exposure on normal lung development.
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PMID:Hyperoxic inhibition of newborn rat lung development: protection by deferoxamine. 179 22

Neonatal rats usually lose their marked tolerance to hyperoxia at about 1 mo of age. We examined the hypothesis that the marked dietary change that occurs at weaning might be important to this loss of O2 tolerance. We, therefore, prematurely weaned rat pups at 15-17 d of age, expecting to find an earlier loss of O2 tolerance. Surprisingly, the prematurely weaned rats showed consistently prolonged relative O2 tolerance compared with normally weaned rats at all ages tested from 35-85 d of life. For example, when challenged with greater than 95% O2 exposure for 7 d, the composite survival rate of the prematurely weaned rats (at 35-85 d of age) was nearly twice that of the normally weaned group (83 of 107 = 78% versus 44 of 107 = 41%, p less than 0.01). In the two experimental groups, nearly all comparative parameters examined were similar, including: 1) growth rate; 2) lung DNA, RNA, and protein; 3) lung antioxidant enzymes and enzyme responses to hyperoxia; 4) lung morphometry; and 5) lung elastin and collagen content. Only serum corticosterone and triiodothyronine levels differed considerably in the two groups. We conclude that premature weaning has a very marked and sustained positive effect on the relative retention of O2 tolerance in the growing rat.
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PMID:Premature weaning of rat pups results in prolongation of neonatal tolerance to hyperoxia. 185 32

Emphysema in humans takes several different forms: centrilobular, panacinar, paraseptal, and airspace enlargement with fibrosis. The varying morphologic and background features of these forms of emphysema suggest that they differ in pathogenesis. Elastic fiber rupture and fraying are a feature of emphysema. Experimental emphysema may be induced by human neutrophil elastase and other elastolytic enzymes but not by nonelastolytic proteases. Disruption of elastic fibers also appears to be the underlying feature of lathyrogen-induced airspace enlargement and of the emphysema in the blotchy mouse. However, there is no evidence of elastic fiber destruction in cadmium-induced airspace enlargement with fibrosis or in emphysema associated with hyperoxia or severe starvation. Thus, elastic fiber disruption is not common to all forms of experimental emphysema. We posit that airspace enlargement may be a stereotyped response of the lungs to different injuries. Emphysema can be induced in experimental animals by repeated induction of pulmonary neutrophilia. However, the evidence for involvement of neutrophil elastase in human emphysema is not clear: there are studies using a variety of approaches that weigh on both sides of the question. There is also in vitro evidence that alveolar macrophages can degrade elastin or elastic fibers with which they are in contact by means of a metalloelastase or the cooperative action of plasminogen activator and an acid cysteine protease. We conclude that the pathogenesis of emphysema is complex. Neutrophil elastase likely plays a major role in the development of some forms of emphysema, but our understanding of the interactions between the alveolar walls and neutrophils is still fragmentary.
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PMID:Putative role of neutrophil elastase in the pathogenesis of emphysema. 206 48

Hyperoxia is routinely administered to patients with severe emphysema. To gain insight into the possibly adverse effects of such treatment, hamsters were exposed to 60% oxygen for 5 days, beginning 48 h after induction of pulmonary emphysema by intratracheal instillment of pancreatic elastase. Control groups consisted of (1) animals instilled with elastase and exposed to room air, (2) animals instilled with saline and exposed to 60% oxygen, and (3) animals instilled with saline and exposed to room air. Cross-linked elastin content and synthesis in the lung were measured immediately following termination of hyperoxia, and the mean linear intercept was determined 4 wk later. Cytologic examination of bronchoalveolar lavage fluids was also performed. Statistical significance was determined by a two-way analysis of variance. Results indicate that exposure to 60% oxygen significantly affected (p less than 0.05) air-space size, causing a 51% increase among elastase-treated hamsters (124 versus 82 microns) but only a 4% increment among saline-treated animals (52 versus 50 microns). When compared to other groups, animals treated with both elastase and hyperoxia had a significantly greater (p less than 0.01) percentage of neutrophils (28%) in their lung lavage fluids immediately following exposure to 60% oxygen. Although total lung elastin content was not altered by hyperoxia at this time, labelling of elastin cross-links was significantly increased (p less than 0.05). These studies demonstrate that exposure to 60% oxygen enhances elastase-induced lung injury. They also raise the possibility that oxygen therapy may, under certain circumstances, accelerate the progression of human emphysema.
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PMID:The effect of 60% oxygen on air-space enlargement and cross-linked elastin synthesis in hamsters with elastase-induced emphysema. 211 71

We studied damage and repair of lung connective tissue in rats exposed to toxic amounts of oxygen by measuring lung content of collagen and elastin and the number of collagen fragments in lung lavage fluid after exposure to 98% O2 for 60 h. Lung collagen was decreased 17%, and collagen fragments in lavage fluid were increased 4- to 5-fold in O2-exposed rats compared with those in control rats. No biochemical evidence of elastin degradation was found. Mild emphysematous changes and a leftward shift of fluid-filled, pressure-volume curves were induced within 2 wk after recovery from exposure to O2. Administration of the lathyrogen beta-aminopropionitrile worsened the emphysematous lesion produced by hyperoxia, suggesting that replacement of connective tissue during repair limits the extent of emphysema. We conclude that lung collagen is degraded and an emphysematous lesion is produced by relatively short exposure to toxic amounts of oxygen.
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PMID:Damage and repair of lung connective tissue in rats exposed to toxic levels of oxygen. 381 7

We investigated whether alpha 1-antitrypsin (alpha 1-AT) might protect neonatal rats from the pulmonary parenchymal and vascular effects resulting from hyperoxic exposure. Neonatal rats born into and maintained in hyperoxia (60% fraction of inspired oxygen) or room air were injected with a loading dose of alpha 1-AT (72 mg/kg) followed by 36 mg/kg every 72 h or with vehicle during the first 14 d of life. At the end of the experimental period, we measured body weight, lung compliance, lung volume, alveoli per mm2, and total number of alveoli and assessed right ventricular hypertrophy and vascular changes consisting of medial hypertrophy, muscular extension into peripheral, normally nonmuscular arteries, and number of peripheral arteries relative to alveoli. Our data show that alpha 1-AT treatment prevented the reduced lung compliance observed in the untreated hyperoxia-exposed neonatal rats, as well as the right ventricular hypertrophy and the associated vascular changes of medial hypertrophy of muscular arteries and muscularization of distal arteries. Reduced lung compliance in the hyperoxic but alpha 1-AT-untreated rats was associated with a reduction in lung elastin compared with room-air or alpha 1-AT-treated rats. In room-air rats, alpha 1-AT treatment increased lung compliance but also reduced the number of arteries relative to the number of alveoli, a feature that was not, however, associated with right ventricular hypertrophy. Our data suggest that supplemental alpha 1-AT might restore the imbalance in elastolytic activity induced by hyperoxia and thereby alleviate the toxic effects on lung parenchymal and vascular development.
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PMID:Alpha 1-antitrypsin protects neonatal rats from pulmonary vascular and parenchymal effects of oxygen toxicity. 789 85

Terminal gas-exchange units in the lung of many species are, at birth, relatively large structures termed saccules. Saccules septate postnatally forming smaller units that constitute the final alveoli. In the rat, septation occurs intensively during the first 2 postnatal wk after which it has been considered to stop. Treatment with dexamethasone or exposure to hyperoxia during the first 2 postnatal wk markedly inhibits septation as evidenced by the formation of fewer and bigger alveoli than in normally developed rats. Deferoxamine, an iron chelator, has been reported to protect the lung from the effects of exposure to hyperoxia in early postnatal life. In this study, we investigated the effects of these treatments during the 3rd and 4th postnatal wk, that is, after the early period of rapid alveolarization. Our results show that treatment with dexamethasone no longer had any inhibitory effect on alveoli formation; that exposure to hyperoxia continued to inhibit the formation of new alveoli, resulting in bigger and less numerous alveoli; that treatment of animals exposed to hyperoxia with deferoxamine still protected their lungs against hyperoxic inhibition; and that elastin fiber length density in the lung was significantly reduced in hyperoxic-exposed animals. These results suggest that septation continues beyond the 2nd postnatal wk and does not stop abruptly at age 14 d in air-breathing rats and that hyperoxic inhibition of alveolarization during the 3rd and 4th postnatal wk is due to the inhibition of septation of existing or newly generated gas-exchange units during that period of lung development.
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PMID:The formation of alveoli in rat lung during the third and fourth postnatal weeks: effect of hyperoxia, dexamethasone, and deferoxamine. 813 76

Normal lung development involves septation of the large air saccules present at birth to form smaller diameter alveoli with a much increased surface area for respiratory exchange. This process in the newborn animal is markedly inhibited by hyperoxia, and the altered lung morphology that results may be permanent. We tested whether treatment of neonatal rats with the new 21-aminosteroid (21-AS) drug, U-74389F (15 mg/kg/d), could protect against O2-induced inhibition of normal lung development. By morphometric analysis after 10 d in > 95% O2, the lungs of the animals treated with this potent iron chelator and inhibitor of lipid peroxidation showed a substantial protective effect--with reduced mean air space diameter and significantly increased internal surface area compared with O2 control pups. [Air control mean air space diameter = 47.4 microns, internal surface area = 1014 cm2; O2 controls = 61.0 microns (increases 29%), 769 cm2 (decreases 24%); O2 21-AS = 53.4 microns (increases 13%), 919 cm2 (decreases 9%); p < 0.05 between O2 groups.] Similarly, inhibition of lung elastin deposition (involved in septation process) during hyperoxia was significantly ameliorated by 21-AS treatment. In addition, follow-up studies of young adult rats demonstrated permanently enlarged lung alveoli and reduced surface area after neonatal high O2 exposure. These chronic morphologic effects were also significantly reduced by neonatal 21-AS treatment.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Protection against acute and chronic hyperoxic inhibition of neonatal rat lung development with the 21-aminosteroid drug U74389F. 837 24

These studies were undertaken to determine the relationship of early changes in the synthesis rates and contents of collagen, elastin, and soluble tissue protein of pulmonary arteries in rats exposed chronically to normobaric hyperoxia. The growth response of pulmonary arteries was characterized by proportionate increases in the contents of the three protein fractions after 7 days (130% of control) and 21 days (194% of control) of exposure. Fractional rates of protein synthesis were assessed both in vivo and in vitro with the use of several radiolabeled amino acids as tracers to minimize uncertainties of the relationships of the specific radioactivities of measured amino acid pools and the precursors for the proteins fractions. Values for fractional synthesis rates of collagen, elastin, and soluble protein in vitro in pulmonary arteries isolated from control rats were 2.2, 1.6, and 19%/day, respectively. Rates of synthesis of collagen and soluble protein in vitro were approximately 20% lower than that determined in control rats in vivo. The fractional synthesis rates of the three protein fractions in isolated arteries from experimental rats were unchanged after 1 day of hyperoxic exposure, decreased marginally after 3 days, and markedly increased after 7 days. At this time the absolute increments in the fractional synthesis rates of collagen (+4.7%/day) and elastin (+5.0%/day) were less than that of soluble tissue protein (+16%/day) and were more comparable to the accumulation rate of proteins in the tissue. The disproportionate increment in the fractional rate of soluble protein synthesis suggests that the fractional rate of degradation of soluble protein was also increased during the growth response in this model of hypertension.
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PMID:Protein synthesis in pulmonary arteries from rats exposed to hyperoxia. 843 Aug 19

Aerobic metabolism requires a continuous oxygen supply, which in turn can form partially reduced species (free radicals) that damage cellular components. To prevent this, organisms have elaborate free radical-scavenging defenses that include the superoxide dismutases. The lungs are unique in their role as an oxygen-gathering system, making these defenses critical to lung integrity. Manganese superoxide dismutase (Mn-SOD) levels increase in rats exposed to sublethal doses of hyperoxia and correlate with the development of tolerance to higher levels of hyperoxia. Although pulmonary Mn-SOD protein and mRNA levels both change with hyperoxia, the timing and levels differ dramatically. Lung heterogeneity makes extrapolation of data from whole tissue homogenates or cultures difficult. In this study, in situ hybridization of Mn-SOD in the lungs of adult rats exposed to air or to 85% O2 for 3 days was performed. In animals exposed to either air or 85% O2, Mn-SOD transcripts were present in arterioles, the septal tips of alveolar ducts, alveolar type II cells, and mesothelial cells. Hyperoxic lung had an intense, continuous labeling of the pleura that was distinctly greater than the intermittent labeling of the pleura found in control animals. The high level of expression of Mn-SOD mRNA in alveolar duct septal tips in both control and O2-exposed animals may be secondary to increased aerobic activity in these regions, which contain collagen and elastin and are important stress-bearing elements in the lung. Alveolar type II cells are metabolically active secretory cells and thus may experience increased endogenously generated oxidative stress. Pleural effusions are common after hyperoxic exposures, suggesting damage to the mesothelium.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Distribution of manganese superoxide dismutase mRNA in normal and hyperoxic rat lung. 848 Dec 34


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