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)

By culturing HeLa cells at stepwise increased oxygen tensions over a prolonged period of time (approximately 21 months) we selected a substrain capable of growing under 80% O2/19% N2/1% CO2, an oxygen level that is lethal to normal HeLa cells, adapted to 20% O2/79% N2/1% CO2. The 80% O2-adapted cells exhibited the following characteristics. At the ultrastructural level an abnormal mitochondrial morphology was observed: compared to normal cells, mitochondria of the hyperoxia-adapted cells exhibited a 3-fold larger mean profile area in sections and were slightly decreased in number; the relative mitochondrial volume was increased 2-fold, whereas the size of both cell types was the same. Mitochondrial matrix appeared less dense in the hyperoxia-adapted cells; no structural damage was detected. Compared to the 20% O2-adapted cells O2 consumption per cell was approximately 40% decreased in the 80% O2-adapted cells. Under hyperoxic conditions 20% O2-adapted and 80% O2-adapted cells exhibited very similar cyanide-resistant respiration rates (0.16 +/- 0.04 and 0.15 +/- 0.02 fmoles/cell/minute, respectively), suggesting that the increased O2 tolerance of the 80% O2-adapted cells was not due to a decreased cellular production of activated oxygen species at hyperoxia. Cellular levels of the enzymes directly involved in protection against activated oxygen species, i.e., superoxide dismutases, catalase, and glutathione peroxidase, were normal or slightly below normal in the 80% O2-adapted cells, implying that these enzymes were of no significance for the increased O2 tolerance. In addition, the specific activity of glucose-6-phosphate dehydrogenase, a key enzyme for cellular production of NADPH, was not related to the degree of O2 tolerance. Our results suggest that the increased O2 tolerance of the 80% O2-adapted cells is neither based on cellular properties controlling the formation or removal of intracellular activated oxygen species nor on the cellular capacity to repair or replace damaged cellular components. We speculate that the increased O2 tolerance is largely due to a genetically determined increased resistance of oxygen-sensitive cellular targets.
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PMID:Some characteristics of hyperoxia-adapted HeLa cells. A tissue culture model for cellular oxygen tolerance. 298 61

The activity of antioxidant enzymes were measured in alveolar type II cells isolated from control and 85% oxygen-exposed rats to determine if type II cells, an oxygen-resistant lung cell type had constitutively high enzyme activities and to measure the effect of hyperoxia on these antioxidant enzyme. Type II cells were isolated from lungs of control rats and rats exposed to 85% O2 for 7 days. In whole lungs of rats exposed to 85% oxygen there is an increase in activity (per lung or per mg lung DNA) in the antioxidant enzymes CuZn superoxide dismutase, Mn superoxide dismutase, catalase, glutathione peroxidase and glucose-6-phosphate dehydrogenase. Oxygen exposure significantly increased (p less than 0.05) all type II cell antioxidant enzyme activities when expressed per mg DNA. The protein content of oxygen exposed type II cells increased 25% from (63.9 +/- 4.8 micrograms/10(6) cells to 79.6 +/- 4.2 micrograms/10(6) cells, p less than 0.05). When type II cell enzyme activities were expressed in U/mg cell protein, only CuZn superoxide dismutase and Mn superoxide dismutase increased in activity following oxygen exposure (by 43% and 28% relative to air exposed lung type II cells, respectively, p less than 0.05). This suggested that most lung cell antioxidant enzymes increased in activity following oxidant stress in proportion to increased cell mass. CuZn and Mn superoxide dismutase increased activity to an extent greater than the increase in type II cell protein content after oxygen exposure. Alveolar macrophages lavaged from control and oxygen-exposed rats were also evaluated, and they had no significant change in CuZn and Mn superoxide dismutase activities. Type II cells accounted for 10% and 17% of alveolar cells in control and oxygen treated rats. By knowing the antioxidant enzyme activities in type II cells, the total enzyme activity of whole lung and the number of type II cells in control and oxygen exposed rats from morphometric data, we calculated the percent of whole lung enzyme activity accounted for by type II cells. Type II cells accounted for a high percentage of lung glucose-6-phosphate dehydrogenase (58% in control rats, 65% in oxygen exposed rats) but a low percentage of Mn superoxide dismutase (4% in control rats, 6% in oxygen exposed rats).
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PMID:Antioxidant enzyme activity in alveolar type II cells after exposure of rats to hyperoxia. 300 82

The present study was conducted on bone tissue responses to irradiation towards a treatment model of mandibular irradiation injury by comparing the results of experimental observations of irradiation effects on rabbit hind legs and rat mandibular bones (paper I, II and III) with clinical observations of irradiation effects on the human mandible (paper IV, V and VI). The main results of the study were as follows: Bone marrow haemorrhage, eosinophilia and incipient edema were encountered in the rabbit leg one day after a single irradiation dose. Edema and fibrosis were the salient features after five weeks, while both regenerative and fibrotic changes predominated eleven weeks after irradiation. The changes were the more extensive the greater the irradiation dose was. Empty lacunae as a sign of cell damage in cortical bone already appeared on the first day after irradiation; this effect reached its maximum when the dose was 20 Gy or more. Bone marrow and subcutaneous tissue pO2 and pCO2 were measured by means of implanted Silastic tonometers in irradiated and nonirradiated rabbit hind legs. Single dose irradiation was followed by a rapid, dose dependent decrease of marrow pO2. The corresponding effect on pCO2 was weaker and appeared later. The response to hyperoxia in the bone marrow became weaker when the irradiation dose increased. Less significant was the response of CO2 tension to hyperoxia. O2 and CO2 tensions were recovered after single dose irradiation both in subcutaneous tissue and in bone marrow, but the reduction was less in bone marrow. During the twelve weeks observation period clearly better recovery in tissue gas tensions was observed in subcutaneous tissue than in bone marrow. Nonirradiated periosteal grafts on irradiated bone cavities in the rabbit tibia induced more rapid and intense mature bone formation than irradiated periosteal grafts. The irradiated periosteum, even after a single dose of 20 Gy, had some osteogenetic capacity. The alkaline phosphatase content was lowered eight weeks after surgery in irradiated legs but clearly exceeded control values twelve weeks after surgery indicating new bone formation. Lysosomal enzyme DAP II contents were increased in all irradiated specimens as a sign of disturbed bone formation. The tissue concentrations of acid phosphatase, cytochrome oxidase, lactate dehydrogenase, isocitrate dehydrogenase, glucose-6-phosphate dehydrogenase and succinate dehydrogenase in the immediate postirradiation period showed a greater increase in activity in the cut lines of the irradiated rat mandibles than in those of the nonirradiated mandibles.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Bone tissue response to irradiation and treatment model of mandibular irradiation injury. An experimental and clinical study. 309 Aug 54

The in vivo effects of hyperoxia were studied in lung colonies formed by B16-F10 melanoma cells in C57BL/6 mice. Several antioxidant defenses were found to change with in vivo exposure: glutathione reductase and glucose-6-phosphate dehydrogenase activities decreased as compared with levels in the cultured cells, glutathione peroxidase activity dramatically increased, and Mn-superoxide dismutase activity and levels of total glutathione were similar in vivo and in vitro. Exposure of tumor-bearing animals to 70%, O2 for 3 weeks did not alter the antioxidant defenses measured in the tumors. One hundred percent O2 exposure did not affect either initial arrest or subsequent retention of radiolabeled B16-F10 cells in the lung. Likewise, hyperoxia did not appear to alter cell division in B16-F10 cells growing in the lung. These results are consistent with our previous studies indicating that the B16-F10 cell line is resistant to levels of O2 in vivo that adversely affect other tumor cell lines.
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PMID:Effects of hyperoxia on B16-F10 cells in vivo. 318 29

Preexposure to hypoxia increased survival and lung reduced glutathione-to-oxidized glutathione ratios (GSH/GSSG) and decreased pleural effusions in rats subsequently exposed to continuous hyperoxia. In addition, lungs from hypoxia-preexposed rats developed less acute edematous injury (decreased lung weight gains and lung lavage albumin concentrations) than lungs from normoxia-preexposed rats when isolated and perfused with hydrogen peroxide (H2O2) generated by xanthine oxidase (XO) or glucose oxidase (GO). In contrast, when perfused with elastase or exposed to a hydrostatic left atrial pressure challenge, lungs isolated from hypoxia-preexposed rats developed the same acute edematous injury as lungs from normoxia-preexposed rats. The mechanism by which hypoxia preexposure conferred protection against H2O2 appeared to depend on hexose monophosphate shunt (HMPS)-dependent increases in lung glutathione redox cycle activity. First, before perfusion with GO, lungs from hypoxia-preexposed rats had increased glutathione peroxidase and glucose 6-phosphate dehydrogenase (but not catalase or glutathione reductase) activities compared with lungs from normoxia-preexposed rats. Second, after perfusion with GO, lungs from hypoxia-preexposed rats had increased H2O2 reducing equivalents, as reflected by increased GSH/GSSG and NADPH/NADPH+, compared with lungs from normoxia-preexposed rats. Third, pretreatment of rats with an HMPS inhibitor, (6-aminonicotinamide) or a glutathione reductase inhibitor, [1,3-bis(2-chloroethyl)-1-nitrosourea] prevented hypoxia-conferred protection against H2O2-mediated acute edematous injury in isolated lungs. These findings suggest that increased detoxification of H2O2 by glutathione redox cycle and HMPS-dependent mechanisms contributes to tolerance to hyperoxia and resistance to H2O2 of lungs from hypoxia-preexposed rats.
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PMID:Hypoxia increases glutathione redox cycle and protects rat lungs against oxidants. 321 62

Mice were given i.v. injections of various tumor cell lines and, beginning 24 h later exposed for 3 weeks to 70% oxygen. Hyperoxia reduced the number of lung colonies derived from MT-7 cells (originally a mammary carcinoma) and of the lung-tumor derived cell lines 498 and Line-1 early passage. Lung colonies derived from Line-1 late passage, lines M109, B16-F10 and Lewis lung carcinoma were oxygen resistant. Lung metastases following i.m. injection of MT-7 cells were oxygen-sensitive and metastases derived from B16-F10 cells or Lewis lung carcinoma were oxygen resistant. Pre-exposure of mice for 48 h to 100% oxygen enhanced colony formation for all cell lines examined whereas exposure to 100% oxygen after i.v. injection only curtailed the growth of the cell lines previously shown to be sensitive to 70% oxygen. There was no correlation between oxygen sensitivity or resistance and the levels of total glutathione or activities of superoxide dismutase (SOD), glutathione reductase or peroxidase or glucose 6-phosphate dehydrogenase in the cell lines. However, upon injection in mice a resistant cell line increased its anti-oxidant defense mechanisms while growing in vivo whereas a sensitive cell line failed to show such adaptation.
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PMID:Effects of hyperoxia on growth of experimental lung metastasis. 334 81

We fed Sprague-Dawley rats either freely or by restricting them to 20% of their usual diet for 21 days. In one experiment, we refed half of the food-restricted rats for 12 h, then exposed the three groups to air or 85% O2 for 5 days. The mortalities in 85% O2 were 100, 33, and 0% for the food-restricted, restricted-refed, and freely fed groups, respectively. In air lung polyamine contents and glucose 6-phosphate dehydrogenase and NADP-dependent isocitrate dehydrogenase activities were significantly lower with food restriction. After hyperoxia, lung polyamine and protein contents and enzyme activities were increased in the two surviving groups, but spermine and DNA contents of refed rats did not increase. In a second experiment, we exposed rats to 60% O2 and found that DNA synthesis of food-restricted rats was lower than the freely fed rats in air and remained low after hyperoxia. We conclude that food restriction increases the mortality from 85% O2 and is associated with lower DNA synthesis and polyamine content. We speculate that food-restricted animals may accumulate greater lung injury partly because of a compromised repair process.
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PMID:Effects of food restriction and hyperoxia on rat survival and lung polyamine metabolism. 339 99

Single, preexposure, parenteral injection with both recombinant tumor necrosis factor/cachectin (TNF/C) and interleukin-1 (IL-1) prolonged the survival of rats (144 +/- 9 h) in continuous hyperoxia (greater than 99% O2 at 1 atm) when compared with rats injected with boiled TNF/C and boiled IL-1 (61 +/- 2 h), TNF/C alone (61 +/- 2 h), IL-1 alone (62 +/- 2 h), or saline (64 +/- 3 h). After exposure to hyperoxia for 52 h, pleural effusion volume, pulmonary artery pressure, total pulmonary resistance, and lung morphologic damage were decreased in those rats given TNF/C and IL-1 as compared with saline-injected rats. In parallel, ratios of reduced (GSH) to oxidized (GSSG) glutathione were greater (P less than 0.05) in lungs of TNF/C + IL-1-injected rats (91 +/- 20) than of saline-injected rats (30 +/- 4) that had been exposed to hyperoxia for 52 h. No differences were found in superoxide dismutase, glutathione peroxidase, glutathione reductase, glucose-6-phosphate dehydrogenase, or catalase activities in lungs of TNF/C + IL-1- or saline-treated, hyperoxia-exposed rats. Our results indicate that pretreatment with TNF/C and IL-1 favorably altered lung glutathione redox status, decreased lung injury, and enhanced survival of rats exposed to hyperoxia.
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PMID:Recombinant tumor necrosis factor/cachectin and interleukin 1 pretreatment decreases lung oxidized glutathione accumulation, lung injury, and mortality in rats exposed to hyperoxia. 349 53

Administration of monoamine oxidase type A inhibitor clorgyline to rats before hyperoxia prevented oxygen-induced increase in diene conjugate and Shiff's base brain and plasma levels in hyperoxia. This was due to antioxidative effect of clorgyline which resulted in stabilization of blood cellular membranes. Clorgyline had a normalizing effect on extraerythrocyte hemoglobin level, total peroxidase activity and glucose-6-phosphate dehydrogenase activity in the serum.
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PMID:[Effect of clorgyline on the intensity of lipid peroxidation and on erythrocyte membrane stability in hyperoxia]. 380 52

The hypothesis was tested that continuous hyperoxia would enhance the development of lung tumors in mice. In strain A/J mice treated with a single dose of urethan (1000 mg/kg) and exposed to 70% O2 for 16 wk, an average of 5 tumors per lung developed, whereas in animals kept in air, an average of 20 tumors per lung was found. When the animals were returned to air after oxygen exposure, it was found that a difference of 15 tumors per lung between the two groups persisted up to 1 yr later, indicating that O2 was tumoricidal. The shortest duration of O2 exposure to be effective was 4 wk, and delay of O2 exposure up to 12 wk after urethan still was effective in reducing the number of developing tumors. Histopathology showed that continued exposure to 70% O2 produced some hyperplasia of the bronchiolar epithelium and only very discrete changes in the pulmonary parenchyma. Analysis of cell proliferation patterns with a continuous [3H]thymidine labeling technique showed a persistent high cell labeling in the bronchiolar epithelium and a temporary increase in alveolar wall cell labeling. Chronic hyperoxia failed to alter the activities of pulmonary superoxide dismutase or glucose-6-phosphate dehydrogenase. Ornithine decarboxylase, on the other hand, was increased as long as the animals remained exposed to oxygen. It was concluded that hyperoxia kills developing tumor cells in mouse lung.
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PMID:Inhibition of mouse lung tumor development by hyperoxia. 394 76

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