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)

Aiming at a better understanding of the pathophysiologic basis of perinatal encephalopathy, we evaluated patterns of tissue oxygenation during hypoxia and hyperoxia. We utilized both laserspectroscopy and invasive tissue-Po2 microneed measurements synchronously in five newborn lambs (141-143 days of gestation). The model of artificial placentation provided defined changes of the blood gases, using a extracorporeal circuit with interposition of membrane lung. During hyperoxia, the Po2 at the blood outlet port of the lung was raised to > 300 mmHg for five minutes. During hypoxia, Po2 was diminished as oxygen at the gas phasis was replaced by nitrogen. After the induction of hyperoxia, a rise of tissue-Po2 was observed. The synchronously recorded data of the laserspectroscopy showed adequately rising HbO2 values in concordance (r = 0.97, p < 0.001). As a constant finding we did not observe Cyt-aa3 changes during induced hyperoxia with tissue-Po2 values of < 40 mmHg. Furthermore, no changes in blood volume occurred in this case. A different pattern of the laserspectroscopic parameters was found when the tissue-Po2 rose above a value of > 40 mmHg and Cyt-aa3 rose after a lag-time occurred. During induced hypoxia an immediate fall of tissue-Po2 corresponding with a fall of HbO2 in the spectroscopic tracing occurred (r = 0.87, p < 0.001). A fall of the Cyt-aa3 level was seen with a lag-time when the tissue-Po2 had reached values of below 10 mmHg. In addition, a rise of blood volume was recorded in all cases of induced hypoxia. In conclusion, the results indicated that cellular redoxe state remains stable over a large range of oxygen partial pressure changes.
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PMID:Cerebral tissue oxygenation during hypoxia and hyperoxia using artificial placentation in lamb. 870 32

It is now possible to detect quantitative changes in cytochrome aa3 by means of near-infrared spectrophotometry. This technique is also suitable for determining oxidised hemoglobin (HbO2), reduced hemoglobin (Hb), cerebral blood volume, and the redox state of cytochrome aa3 (cyt aa3) in the tissues. The significance of elevated cyt aa3, measured by near-infrared spectrophotometry, is still unclear, so we investigated this question using both near-infrared spectrophotometry and oxygen saturation meters in endotoxemic dogs. Ten anaesthetised mongrel dogs were injected with endotoxin (E. coli 0111: B4 Difco 2 mg/kg i.v.) and the redox state of Hb and cyt aa3 was determined in real time by near-infrared spectrophotometry. The levels of arterial and cisternal venous oxygen saturation were recorded simultaneously by two Oximetrix 3 saturation meters to calculate the cerebral arterial and venous oxygen saturation difference (Sata-vO2D) in real time. HbO2 decreased along with the fall in mean arterial pressure and remained at a low level, while Hb increased and remained at a high level. The cerebral blood volume decreased in the endotoxic early stage and then returned gradually towards baseline. Cyt aa3 showed an increase following endotoxin injection and maintained an oxidised form. The cerebral Sata-vO2D rose to about three times the control level. From these observations, an increase of oxidised cytochrome aa3 after endotoxin administration seems to be a compensatory protective effect in response to the cerebral oxygen demand rather than over-oxygenation or hyperoxia.
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PMID:Significance of elevated cytochrome aa3 in a state of endotoxemia in dogs. 895 75

A mev-1(kn1) mutant of the nematode Caenorhabditis elegans is defective in the cytochrome b large subunit (Cyt-1/ceSDHC) in complex II of the mitochondrial electron transport chain. We have previously shown that a mutation in mev-1 causes shortened life span and rapid accumulation of aging markers such as fluorescent materials and protein carbonyls in an oxygen-dependent fashion. However, it remains unclear as to whether this hypersensitivity is caused by direct toxicity of the exogenous oxygen or by the damage of endogenous reactive oxygen species derived from mitochondria. Here we report important biochemical changes in mev-1 animals that serve to explain their abnormalities under normoxic conditions: (i) an overproduction of superoxide anion from mitochondria; and (ii) a reciprocal reduction in glutathione content even under atmospheric oxygen. In addition, unlike wild type, the levels of superoxide anion production from mev-1 mitochondria were significantly elevated under hyperoxia. Under normal circumstances, it is well known that superoxide anion is produced at complexes I and III in the electron transport system. Our data suggest that the mev-1(kn1) mutation increases superoxide anion production at complex II itself rather than at complexes I and III. The mev-1 mutant also had a lactate level 2-fold higher than wild type, indicative of lactic acidosis, a hallmark of human mitochondrial diseases. These data indicate that Cyt-1/ceSDHC plays an important role not only in energy metabolism but also in superoxide anion production that is critically involved in sensitivity to atmospheric oxygen.
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PMID:A defect in the cytochrome b large subunit in complex II causes both superoxide anion overproduction and abnormal energy metabolism in Caenorhabditis elegans. 1152 63

The mev-1(kn1) mutation of Caenorhabditis elegans is in Cyt-1, which encodes a subunit of succinate-coenzyme Q oxidoreductase in the mitochondrial electron transport chain. Mutants are hypersensitive to oxidative stress and age precociously in part because of increased superoxide anion production. Here, we show that mev-1 mutants are defective in succinate-coenzyme Q oxidoreductase, possess ultrastructural mitochondrial abnormalities (especially in muscle cells), show a loss of membrane potential, have altered CED-9 and Cyt-1 protein levels under hyperoxia, and contain ced-3-and ced-4-dependent supernumerary apoptotic cells. These defects likely explain the failure of mev-1 to complete embryonic development under hyperoxia as well as its reduced life span.
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PMID:A complex II defect affects mitochondrial structure, leading to ced-3- and ced-4-dependent apoptosis and aging. 1267 28