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

The purpose of this study is to examine effects of hyperoxic gas mixtures on changes of blood indices during bicycle exercise of human. Oxygen-enriched gases (30% O2) were inspired during the ramp load exercise of 25 watt/min. Changes of blood indices were analyzed with Sequential Multiple Analyzer with the computer (SMAC). The improvement of exercise performance were discussed about relationship between function of hyperoxic gas and physiological mechanism. Three experimental conditions were set as follows (I) 30% O2 +N2 gases balance, (II) air (21% O2), and (III) 30% O2 +2% CO2 +N2 gases balance. Arterial blood were sampled from the radial artery of the forearm in order to analyze following items; 1) pH level, PaO2, PaCO2, and HCO3 of these blood gases, 2) Blood sugar, TG, and F-CH of the blood contents, 3) red blood corpuscle, white blood corpuscle, Hb, and Ht values, 4) LDH, CK, GOT, and GPT of the blood enzymes, 5) TP, ALB, Na, K, Ca and Cl of the electric ions. In the case of inspiring hyperoxic gases, the recovery rate of blood indices increased after this ramp load exercise remarkably, and the whole exercise metabolism were removed from acidosis tendency to alkalosis value of the resting condition significantly. At hyperoxic experimental conditions, the blood sugar and oxygen consumption were much more decreased than these at normal oxygen content one during both states of exercise and recovery times. These data of the blood indices would support strongly to the hypothesis that improvement of oxygen delivery should be depended upon the enhanced performance with the hyperoxic gases. There might be effects of the hyperoxia on the cellular metabolism and on function of the vascular muscle during those aerobic exercise.
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PMID:[Effects of breathing high concentrations of oxygen on changes in blood indices during bicycle exercise]. 238 13

Sufficient oxygenation is indispensable for cognitive performance in mammals. In order to assure adequate oxygenation and to prevent hypoxia in medicine or aviation, different approaches of oxygen delivery are realized. With regard to hyperoxia, it is well known that it increases the risk of tissue toxicity and inflammation by generating radical oxygen species. However, this impact of hyperoxia on the expression of specific brain proteins has not been evaluated in detail yet. The present study analyzes time-dependent changes in protein expression in rat brain after a short-term exposure to normobaric hyperoxia. Thirty-six Wistar rats were randomly assigned to six different groups, three normobaric hyperoxia (NH) groups or three normobaric normoxia (NN) groups, each consisting of n = 6 animals. NH animals were exposed to 100% oxygen, NN rats to 21% oxygen, each group for 3 h. One group of NH and one group of NN were killed immediately after the 3 h, one group each after 3 days and one group each after 7 days. Rat brains were removed for analysis and whole brain detergent protein lysates were separated via two-dimensional gel electrophoresis followed by subsequent identification of protein expression alterations by peptide mass fingerprinting using mass spectrometry. Also, a functional network mapping and molecular pathway analysis were carried out. Statistical analysis was performed using analysis of variance (ANOVA) with Bonferroni correction using P < 0.01. Physiological parameters of the animals did not differ significantly between the two groups except for partial oxygen pressure (580 vs. 89 mmHg; P < 0.05). The expression of nine proteins was found to be significantly altered (five up-regulated: GOT1, CCT2, TCP1, G6PD, and ALB; four down-regulated: PEBP1, PRDX2, ENO1, and MDH1). IPA generated a network with eight focus proteins associated with pathways in "cell death, cancer, and signalling". Although hyperoxia was normobaric and induced for only 3 h, significant changes in brain protein expression were detectable immediately after the 3 h, after 3 days, as well as after 7 days. This may indicate effects on brain protein expression take place in the rat brain following a relatively short period of hyperoxia.
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PMID:Time-dependent alterations of cerebral proteins following short-term normobaric hyperoxia. 2004 28