UMLS:C0034063 - FACTA Search

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Query: UMLS:C0034063 (pulmonary edema)
10,665 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Prenatal dexamethasone (DEX) treatment is known to accelerate the maturation of both the surfactant system and the fetal lung antioxidant enzyme (AOE) system (Frank L, Lewis P, Sosenko IRS: Pediatrics 75:569-574, 1985). Because of this stimulatory effect of prenatal DEX on the normal late gestational development of the AOE system, we questioned whether this treatment might have a salutary effect on the ability of the newborn rat to tolerate early and prolonged exposure to hyperoxia, inasmuch as the AOE are the primary lung defensive system against high O2 challenge. In nine experiments with term newborn rats in greater than 95% O2, the composite percentage of survival was significantly greater in the prenatal DEX pups at all time periods in hyperoxia from 7 d [control pups, 67 of 94 (71%); prenatal DEX, 96 of 99 (97%)] to 14 d [controls, 10 of 32 (31%); prenatal DEX, 18 of 33 (55%)] (p less than 0.01). In addition to survival per se, the prenatal DEX pups showed significantly decreased lung wet weight/dry weight ratios, pathologic evidence of pulmonary edema, and lung conjugated dienes versus the O2 control newborn group. Of the many comparative parameters examined, the major difference found between the two groups was in the pulmonary AOE responses to hyperoxia. By 2 d in hyperoxia, the prenatal DEX rat pups showed significantly elevated superoxide dismutase, catalase, and glutathione peroxidase activities compared to air control pups, and at 4 and 7 d in O2 the AOE levels were consistently greater in the DEX group than the AOE responses in the control O2 pups.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Prenatal dexamethasone treatment improves survival of newborn rats during prolonged high O2 exposure. 150 13

Tracheal insufflation of tumor necrosis factor (TNF; 5 micrograms or 1.2 x 10(5) U) markedly enhanced the survival of adult rats exposed to 100% O2: 12 of 17 rats (71%) survived for greater than 11 days, whereas 30 of 30 control (Hanks' balanced salt solution) insufflated rats (100%) died within 3 days of O2 exposure. Insufflation of gamma-interferon (5 micrograms) or intraperitoneal injection of up to 40 micrograms TNF did not afford any protection. At 55 h after O2 exposure, TNF-insufflated rats showed less pulmonary edema, as determined by the extravascular lung water content-to-bloodless lung dry weigh ratio and less alveolar capillary leak as determined by the protein content in the bronchoalveolar lavage fluid, than control insufflated rats similarly exposed. This protection against O2 toxicity by TNF insufflation was associated with increased lung superoxide dismutase, catalase, and glutathione peroxidase activities. The enhancement of lung antioxidant enzyme activities was noted at 55 h of O2 exposure, when control animals began to die of O2 toxicity. This temporal relationship suggests that TNF-induced increase in antioxidant enzyme activities contributes, at least in part, to the observed protection.
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PMID:Tracheal insufflation of tumor necrosis factor protects rats against oxygen toxicity. 234 45

We report a new protocol for inducing marked tolerance to prolonged exposure to hyperoxia in adult rats that entails the use of a single "rest period" between exposures to a usually lethal concentration of O2. Exposure of adult rats to greater than 95% O2 for 48 h followed by a rest in air, or a rest even in 50-75% O2, consistently resulted in 100% survival with evidence of only slight pulmonary edema during continuation of exposure to greater than 95% O2 for 3-7 more days (7-day survival for rats rested in room air for 24 h = 23/23; for rats rested in 50-75% O2 for 24 h = 27/27; for continuously O2-exposed control rats = 0/11). Induction of tolerance to hyperoxia was associated with significant increases in the lungs' antioxidant enzyme activities during the reexposure to greater than 95% O2 following the rest period. The molecular means by which the events in this protocol lead to increased lung antioxidant enzyme activity is only partially known, but because of the marked tolerance produced, the elucidation of the mechanisms must be important to our understanding of tolerance to hyperoxia.
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PMID:New "rest period" protocol for inducing tolerance to high O2 exposure in adult rats. 280 50

Hyperoxic adult rats have prolonged survival and reduced morphological evidence of lung injury when treated with a single dose of bacterial endotoxin; this effect is mediated by an augmentation of antioxidant enzyme activity in lung homogenate. To determine whether endotoxin would prolong survival and influence antioxidant enzyme levels in lambs whose physiological response to O2 breathing can be serially measured, we administered a single intravenous dose of endotoxin (0.75 microgram/kg body wt) to 13 lambs before exposing them to greater than 95% O2 (n = 11) or air (n = 2). Seven additional lambs were placed in O2 after receiving only saline vehicle. All lambs had been instrumented to measure pulmonary vascular pressures and cardiac output, and 10 lambs had lung lymph fistulas. O2-exposed control lambs developed noncardiogenic pulmonary edema and respiratory failure within 85 +/- 10 h (range 76-110 h); antioxidant enzymes were not increased, but reduced glutathione (GSH) levels fell and oxidized glutathione (GSSG) increased, reflecting the oxidant stress of O2 exposure. By contrast, endotoxin-treated O2-exposed lambs had a delayed increase in microvascular permeability to protein, a reduced rate of lung edema formation, normal gas exchange after 72 h in O2, and prolonged survival (136 +/- 15 h; range 90-160 h; all variables P less than 0.05). Despite prolonged survival, postmortem lung water content was no greater in the lambs that received endotoxin. Treatment with endotoxin did not increase antioxidant enzyme levels in lung homogenate, but levels of GSH relative to GSSG were significantly elevated.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Pulmonary O2 toxicity in lambs: physiological and biochemical effects of endotoxin infusion. 305 84

Endotoxin treatment of adult rats before hyperoxic exposure significantly increases their survival rate in >95% O(2) (J. Clin. Invest.61: 269, 1978). In this study, we wished to determine: (a) whether endotoxin would protect against O(2) toxicity if it were administered after the animals were already in >95% O(2) for 12-48 h; and (b) the relationship between the endogenous antioxidant enzymes of the lung and the protective effect of endotoxin treatment. Our results showed that adult rats given a single 500 mug/kg dose of endotoxin up to 36 h after the onset of O(2) exposure had significantly increased survival rates and decreased lung fluid accumulation compared to untreated animals in O(2) (P < 0.05). (Survival, 16/49 [untreated rats]; 18/20 [endotoxin at 12 h after the start of O(2) exposure]; 25/26 [endotoxin-24 h]; 15/20 [endotoxin-36 h].)Endotoxin-treated animals in O(2) showed increases in pulmonary superoxide dismutase, catalase, and glutathione peroxidase activities before the usual time of onset of measurable pulmonary edema in untreated animals in O(2). When diethyldithiocarbamate was used to block the superoxide dismutase enzyme rise in the endotoxin-treated rats in O(2), the protective action of endotoxin against pulmonary O(2) toxicity was nullified. In endotoxin-treated, O(2)-exposed mice, there were no lung antioxidant enzyme increases, and no protective effect from O(2) toxicity was achieved. We conclude that, in the rat, a single dose of endotoxin given even 36 h after the onset of hyperoxic exposure results in marked protection against O(2)-induced lung damage; and the increased lung antioxidant enzyme activity in the endotoxin-treated rats appears to be an essential component of this protective action.
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PMID:Potection from oxygen toxicity with endotoxin. Role of the endogenous antioxidant enzymes of the lung. 624 6

Endotoxin treatment in normal rats has a marked protective effect against O2 toxicity (J. Appl. Physiol.: Respirat. Environ. Exercise Physiol. 47: 577-581, 1979 and 51: 577-583, 1981), and endotoxin's protective action is associated with stimulation of the lung's enzymatic antioxidant defense system (superoxide dismutase, catalase, glutathione peroxidase, and glucose-6-phosphate dehydrogenase). Vitamin E-deficient animals are especially sensitive to hyperoxidant stresses, including pulmonary O2 toxicity. In these studies we tested whether endotoxin could reverse the increased susceptibility of vitamin E-deficient rats to hyperoxic challenge. We found that untreated vitamin E-deficient rats do succumb more readily to O2 toxicity [0/11 alive at 72 h in greater than 95% O2, lethal time for 50% of the animals (LT50) = 50 h] than rats fed a regular diet (4/14 alive, LT50 = 69 h). In contrast, 15 of 16 vitamin E-deficient rats treated with endotoxin survived the same O2 exposures (P less than 0.001) and showed significantly reduced pulmonary edema compared with the other groups. The endotoxin-treated vitamin E-deficient group was also the only one to demonstrate significant elevations of all the antioxidant enzymes during O2 exposure, suggesting that the antioxidant enzyme defenses of the lung have a more primary and important role in prevention of O2-induced lung injury than the lipid-associated antioxidant, vitamin E.
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PMID:Endotoxin treatment protects vitamin E-deficient rats from pulmonary O2 toxicity. 638 80

The antioxidant enzyme superoxide dismutase (SOD) found in the cytosol of eucaryotic cells and the plasma protein ceruloplasmin are copper containing proteins though to be important in providing protection from oxygen toxicity. To investigate the hypothesis that copper deficiency in the rat could result in decreased lung SOD activity and plasma ceruloplasmin concentration resulting in increased susceptibility to O2 lung damage, we performed a series of experiments exposing copper-deficient and control rats to normobaric and hyperbaric hyperoxia. Lung SOD activity in the copper-deficient rats was found to be 56% of control and ceruloplasmin content was 6% of control. The copper-deficient rats exhibited increased mortality and enhanced pulmonary toxicity as evidenced by increased pathologic damage and lung edema during the normobaric exposure to 85% O2. Copper-deficient animals also showed increased susceptibility to a hyperbaric exposure of 4 ata of 100% O2 with a decreased time of survival. The copper-deficient rat represents a new model for the study of oxidant injury.
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PMID:Enhanced pulmonary toxicity in copper-deficient rats exposed to hyperoxia. 672 91

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

Selenium (Se) is a component of the antioxidant enzyme glutathione peroxidase (GSHPx). We wanted to determined whether Se deficiency predisposes to pulmonary O2 toxicity. Sixteen weanling rats were fed a Se-free diet (Se-). Sixteen rats fed the same diet had drinking water supplemented with 400 micrograms.l-1 sodium selenite (Se+). After 5 weeks, rats were killed after exposure to either 95% O2 or air for 36 h. Se concentration in blood, lung, liver, heart, muscle and spleen, and blood GSHPx activity were higher in Se+ than in Se- groups. Pulmonary oedema developed in both O2-exposed groups, but was more severe in Se-O2 group than in the Se+O2 group, as judged by the presence of pleural effusions (7 out of 8 versus 0 out of 8), elevated lavage protein concentration (173 +/- 17 versus 120 +/- 14 micrograms.ml-1), and higher wet/dry weight ratio (W:D) (5.8 +/- 0.07 versus 5.4 +/- 0.07). W:D correlated inversely with lung Se content in O2-exposed rats. Both O2-exposed groups had a reduction in the amount of less aggregated lavage phospholipid (PL) compared with the Se+air group. However, the Se-O2 group had increased total PL, because of an increase in more aggregated PL. We conclude that Se deficiency exacerbates pulmonary injury in O2-exposed rats, and that O2 toxicity is associated with an altered physical form of alveolar surfactant.
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PMID:Selenium deficiency augments the pulmonary toxic effects of oxygen exposure in the rat. 828 48

It is an honor, and indeed fitting, to have a chapter on pulmonary oxygen toxicity included in a Festschrift for Dan Gilbert, whose contributions to the free radical theory of oxygen toxicity have been a catalyst to the last half-century of investigation in this field. There is cellular damage that results in pulmonary edema and even death if the increase in reactive oxygen species produced in the lung during exposure to hyperoxia is not counterbalanced by an increase in the cell's antioxidant defense systems. In this chapter experimental evidence will substantiate the importance of post-transcriptional regulation of antioxidant enzyme gene expression in animal models of pulmonary oxygen toxicity and tolerance to hyperoxia with special emphasis given to the role of manganese superoxide dismutase (MnSOD) synthesis, specific activity, and RNA half-life and to a proposed function of a MnSOD RNA-binding protein as a positive regulator in the control of translational efficiency.
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PMID:Post-transcriptional regulation of lung antioxidant enzyme gene expression. 1086 32

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