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)

It has been shown experimentally that a 30-day exposure of white rats to hypokinesia and moderate hyperoxia decreases elimination of ammonia and increases the formation and release into an enclosed atmosphere of carbon monoxide, aldehydes and ketones. The level of metabolism of prophyrin and nitrogen containing compounds as well as of fats and carbohydrates is higher during a combined effect of hypokinesia and moderate hyperoxia than during their separate influences.
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PMID:[Effect of hyperoxia and hypokinesia on the formation and excretion of gaseous metabolic products in rats]. 0 3

The content of ammonia, glutamine, dicarboxylic amino acids and GABA was studied in the brain under 1, 2, 4-fold separate and simultaneous effect of hypothermia (19-20 C) and hyperoxia (3 atm.). A two-fold hypothermia of rats is accompanied by a greater increase of ammonia in the brain than a three-fold one. The content of glutamine under two-fold cooling is unchanged and under three-fold cooling it is twice as low as compared to its content in the brain of the control rats. The content of glutamic acid decreased after two-fold hypothermia is almost unchanged by the third seance of hypothermia. The repeated actions of hyperoxia also cause a considerable increase in the ammonia content but the dynamics of changes in the content of the nitrogenous metabolic products is contary to that in animals subjected to repeated seances of hypothermia. A simultaneous combined action of hypothermia and hyperoxia produces no additive effect on the system ammonia-glutaminic acid.
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PMID:[Effect of hypothermia and hyperoxia on the ammonia-glutamic acid system in the brain of rats]. 96 Feb 39

The intent of this paper is to review the recent literature on exercise-induced hyperammonemia (EIH) and to compare the current interpretations of ammonia accumulation during exercise with the recognized clinical symptoms of progressive ammonia toxicity. In doing so, we will speculate on possible exercise-induced symptoms of CNS dysfunction which could result from elevated ammonia during intense short-duration or prolonged exercise. Ammonia is a ubiquitous metabolic product producing multiple effects on physiological and biochemical systems. Its concentration in several body compartments is elevated during exercise, predominantly by increased activity of the purine nucleotide cycle (PNC) in skeletal muscle. Depending on the intensity and duration of exercise, muscle ammonia may be elevated to the extent that it leaks (diffuses) from muscle to blood, and thereby can be carried to other organs. The direction of movement of ammonia or the ammonium ion is dependent on concentration and pH gradients between tissues. In this manner, ammonia can also cross the blood-brain barrier (BBB), although the rate of diffusion of ammonia from blood to brain during exercise is unknown. It seems reasonable to assume that exhaustive exercise may induce a state of acute ammonia toxicity which, although transient and reversible relative to disease states, may be severe enough in critical regions of the CNS to affect continuing coordinated activity. Regional differences in brain ammonia content, detoxification capacity, and specific sensitivity may account for the variability of precipitating factors and latency of response in CNS-mediated dysfunction arising from an exercise stimulus, e. g., motor incoordination, ataxia, stupor. There have been numerous suggestions that elevated ammonia is associated with, or perhaps is responsible for, exercise fatigue, although evidence for this relies extensively on temporal relationships. Fatigue may become manifest both as a peripheral organ or central nervous system phenomenon, or combination of both. Thus, we must examine the sequential or concomitant changes in ammonia concentration occurring in the periphery, the central nervous system (CNS), and the cerebrospinal fluid (CSF) induced by any effector, not only exercise, to interpret and rationalize the diverse physical, physiological, biochemical, and clinical symptoms produced by hyperammonemic states. Since more is known about elevated brain ammonia during other diverse conditions such as disease states, chemically induced convulsion, and hyperbaric hyperoxia, some of these relevant data are discussed.
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PMID:Exercise-induced hyperammonemia: peripheral and central effects. 219 91

The effect of hyperoxia on lactate production and release and the mitochondrial NAD+-to-NADH ratio was studied in the in situ canine gastrocnemius to determine whether elevated PO2 altered metabolic regulation. Dogs breathed either air (21% O2) [arterial O2 partial pressure (PaO2) 90 mmHg; n = 8] or hyperoxia (100% O2) (PaO2 546 mmHg; n = 8). The left muscle was stimulated for 10 min at 3 Hz and then both right and left muscles were quick frozen in N2. Hyperoxia did not affect O2 uptake, blood flow, and developed tension. Activity increased glucose 6-phosphate (G-6-P), D-fructose 6-phosphate (F-6-P), NH3, lactate, and F-6-P/F-1,6-P in both treatment groups. No significant differences in arterial or venous lactate, muscle lactate, glucose uptake, or glycogen depletion were noted in hyperoxia. Cytoplasmic NAD+/NADH was in a more oxidized state in hyperoxia at rest but not during activity. The increase in NH3 with stimulation was significantly larger in hyperoxia. Activity decreased alpha-ketoglutarate in hyperoxia but not in air. At stimulation, the estimated mitochondrial NAD+/NADH increased in both groups suggesting that hypoxia was not present. Thus hyperoxia did not affect mitochondrial redox state or lactate production and release in active muscle.
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PMID:Hyperoxia, mitochondrial redox state, and lactate metabolism of in situ canine muscle. 361 62

Investigations using nonsteady-state and fatiguing exercise protocols have demonstrated a strong relationship between ammonia and lactate metabolism and have suggested a cause and effect relationship between these two variables. We investigated the lactate-ammonia response using prolonged exercise and inspiration of hyperoxic gas (60% O2-40% N2). The exercise consisted of either 70-75% maximal O2 uptake (VO2 max) for 40 min (series 1, n = 6) or 75-80% VO2max for 30 min (series 2, n = 6) with the subjects inspiring room air on one occasion and hyperoxia in the other test. In both series blood ammonia rose continuously throughout the exercise regardless of the inspired gas treatment; in contrast blood lactate did not increase after 10 min with room air, and with hyperoxia blood lactate was reduced. Muscle lactate and ammonia (series 2; vastus lateralis) had responses similar to the blood data. The data demonstrated no apparent lactate-ammonia relationship with prolonged exercise or in response to hyperoxia, suggesting that ammonia production can be independent of lactate metabolism. The data also suggest that type I fibers can be a major source of ammonia in humans.
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PMID:Muscle and blood ammonia and lactate responses to prolonged exercise with hyperoxia. 369 80

The role of ammonia in exercise-induced fatigue is reviewed. Implications for integrated activity of developing hyperammoneic states, caused by various precipitating conditions such as exercise, liver dysfunction, hypoxia, hyperoxia, and chemical poisoning are described. The central role of ammonia in diverse important metabolic pathways indicates its ubiquitous role in a spectrum of activity ranging from elite exhaustive performance of sportsmen and -women to life-threatening organ dysfunction. The action of ammonia and metabolites from associated pathways in producing seemingly dangerous short term conditions, but inducing possible long term protection against degenerative processes associated with ageing (free radical-induced cellular damage) indicate the paradoxical position of ammonia and its associated metabolic pathways for health and disease processes.
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PMID:Ammonia as an indicator of exercise stress implications of recent findings to sports medicine. 388 58

Plasma ionic status and renal excretion of acidic equivalents and electrolytes were continuously monitored in the freshwater rainbow trout (Salmo gairdneri) during 24 h normoxia (PIO2 = 120-150 torr; control); 72 h hyperoxia (PIO2 = 500-600 torr), and 24 h return to normoxia. Plasma [Cl-] progressively declined in approximate equivalence to the rise in [HCO-3] which compensated the respiratory acidosis of hyperoxia, while [Na+] increased only slightly. [Ca2+] and [K+] rose, [phosphate] declined, and [NH+4] was unchanged. During normoxic recovery, the [Na+], [Cl-] and [HCO-3] changes were reversed, [K+] and [Ca2+] showed further elevations, and [NH+4] increased sharply . Renal acid output increased greatly during hyperoxia with elevations in both NH+4 and titratable components, though the latter predominated due to a marked elevation of phosphate excretion. Renal efflux rates of other electrolytes were generally homeostatic for ECF composition, with increased Na+, K+, and Ca2+ effluxes, and decreased Cl- efflux. Clearance calculations indicated that net tubular reabsorption increased for Cl-, fell for Na+ and K+, and changed over to marked net secretion for phosphate, while net ammonia secretion increased. Most trends were reversed upon return to normoxia. The critical role of phosphate in urinary electrolyte balance and acid-base regulation is emphasized. The net renal excretion of acidic equivalents accounted for only 7-10% of the total compensation observed for the whole animal during hyperoxia. The kidney contributed primarily in conserving ECF HCO-3 and secondarily in balancing branchial exchanges.
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PMID:The mechanisms of acid-base and ionoregulation in the freshwater rainbow trout during environmental hyperoxia and subsequent normoxia. II. The role of the kidney. 672 70

CNS oxygen (O2) toxicity is complex, and the etiology of its most severe manifestation, O2 convulsions, is yet to be determined. A role for depletion of the brain GABA pool has been proposed, although recent data have implicated production of reactive O2 species, e.g. H2O2, in this process. We hypothesized that the production of H2O2 and NH3 produced by monoamine oxidase (MAO) would lead to depletion of GABA and production of nitric oxide (NO.) respectively, and thereby enhance CNS O2 toxicity. In this study, rats treated with an MAO inhibitor (pargyline) or a nitric oxide synthase inhibitor (LNNA) were protected against O2-induced convulsions. Selected cerebral amino acids including arginine were measured in control and O2 treated rats (6 ATA, 20 min) with or without drug pretreatment. After O2 exposure, the cerebral pools of glutamate, aspartate, and GABA decreased significantly while glutamine content increased relative to control (P < 0.05). After treatment with either enzyme inhibitor, glutamine, glutamate and aspartate concentrations were maintained near control levels. Remarkably, GABA depletion by O2 was not prevented despite protection from seizures by both pargyline and LNNA. The NO. precursor, arginine, was increased significantly in the brain by toxic O2 exposure, but both pargyline and LNNA inhibited this effect. Simultaneous norepinephrine measurements indicated that its storage substantially decreased during hyperoxia (P < 0.05), but this effect too was blocked by either pargyline or LNNA. These data indicate that protection against O2 by these inhibitors is not related to preservation of the GABA pool. More importantly, O2 dependent norepinephrine metabolism and NO. synthesis appear to be interactive during CNS O2 toxicity.
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PMID:Cerebral amino acid, norepinephrine and nitric oxide metabolism in CNS oxygen toxicity. 846 4

Neuroendrocrine and substrate responses were investigated in eight male athletes during inhalation of either 100% O2 (HE), 14% O2 (HO) or normoxio gas (NO) before, during and after 60 min of cycle ergometry at the same absolute work rate. Concentrations of prolactin (PRL), growth hormone (GH), testosterone (T), adrenocorticotropic hormone (ACTH), cortisol (COR), adrenalin (A), noradrenalin (NA), insulin (INS), ammonia (NH3), free fatty acids, serotonin (5-HT), total protein, branched-chain amino acids (BCAA) and free tryptophan (free TRP) were determined in venous blood and lactate concentration [LA-], partial pressure of oxygen (PO2), oxygen saturation (SO2), partial pressure of carbon dioxide and pH in capillary blood. The PO2 and SO2 were augmented in HE and decreased in HO (P < or = 0.01). In HO and NO no significant changes were found for any other parameter during 30 min of rest prior to exercise. In HE, PRL increased by about 400% during this time, while NA declined (P < or = 0.01). Heart rate (HR) and [LA-] were higher during exercise in HO (P < or = 0.01). In all trials, NH3, NA, A, T, GH and ACTH increased during exercise (P < or = 0.01), while BCAA and INS declined. In comparison to NO and HE, increases of NA, A, GH, COR and ACTH were higher in HO (P < or = 0.01). The PRL in NO and COR in NO and HE did not change significantly. In HE, after the initial increase at rest, PRL declined during exercise but remained higher than in HO. Higher values for NA, A, GH, COR and ACTH in HO were likely to have reflected an augmented relative exercise intensity. Our results showed that PRL but no other hormone increased during acute exposure to hyperoxia. This PRL release was independent of exercise stress and greater than PRL augmentation during hypoxia, which was related to a higher relative exercise intensity as indicated by [LA-] and HR. Responses of plasma NH3, BCAA, free TRP and 5-HT could not explain PRL augmentation induced by the increment in blood SO2 during hyperoxia.
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PMID:Effect of O2 availability on neuroendocrine variables at rest and during exercise: O2 breathing increases plasma prolactin. 895 92

Urea levels were measured in the saliva of 30 patients with acute and chronic maxillofacial inflammation treated with multiple modalities including hyperbaric oxygenation (HBO). Urea concentrations were evaluated before, in the course of and after HBO session. A total of four 40-min sessions were made (1 session a day, 1.5 atm). Elevated concentrations of urea after HBO are thought adaptive, serving for elimination of ammonia overproduction in hyperoxia. Urea measurements in the saliva can be used for prediction of oxygen intoxication in the HBO-exposed patients.
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PMID:[The effect of hyperbaric oxygenation on the urea content of the saliva in acute and chronic soft-tissue inflammation in the maxillofacial area]. 995 Dec 97

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