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)

Mitochondrial energy coupling in the gerbil brain was characterized by the relationship between intracellular phosphocreatine (PCr)/inorganic phosphate (Pi), phosphorylation ratio, and the mitochondrial redox state in graded hypoxia. Phosphorus-nuclear magnetic resonance (NMR) spectra of the brain and whole head were taken by surface and saddle coil, respectively. The NADH level of the brain cortex was monitored by in vivo fluororeflectometry. The PCr and Pi of the head and brain did not change between 100 and 10% O2 inhalation. PCr progressively decreased and Pi progressively increased with 6 and 4% 0% inhalation in the head. The PCr/Pi of the brain decreased by 44% at 6% fraction of inhaled oxygen (FIO2) and 57% at 4% FIO2. The ATP level did not change during hypoxia. The calculated phosphorylation ratio of the brain ([PCr] Kck[H+]/[Cr][Pi]) = ([ATP]/[ADP][Pi]) was 4.1 X 10(4) M-1 in normoxia. Hypoxia of increasing severity induced increasing NAD reduction of the brain cortex with 17% NAD reduction at 10% FIO2 when there was no change in phosphorylation ratio. The phosphorylation ratio decreased, i.e., the mitochondria failed to maintain the energy level of the brain when the magnitude of the change in NAD reduction to hypoxia was half of the total redox change between hyperoxia and anoxia. These studies demonstrated the feasibility of combined 31P-NMR and NADH fluorometry measurements on brain in vivo. The observations show similarities between the responses of mitochondrial oxidative phosphorylation to hypoxia in vivo and in vitro.
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PMID:Correlated in vivo 31P-NMR and NADH fluorometric studies on gerbil brain in graded hypoxia and hyperoxia. 336 55

The effects of hypoxic hypoxia on high-energy phosphate metabolites and intracellular pH (pHi) in the brain of the anesthetized infant rabbit were studied in vivo using 31P nuclear magnetic resonance spectroscopy. Five 10- to 16-day-old rabbits were anesthetized with 1.5% halothane. Ventilation was controlled to maintain normocarbia. Inspired O2 fraction was adjusted to produce three states of arterial oxygenation: hyperoxia (PaO2 greater than 250 mm Hg), normoxia (PaO2 approximately 100 mm Hg), and hypoxia (PaO2 25-30 mm Hg). During hypoxia, blood pressure was kept within 20% of control values with a venous infusion of epinephrine. During hyperoxia, the phosphocreatine-to-ATP ratio was 0.86, a value that is 2-2.5 times less than that reported for adults. During normoxia, ATP decreased by 20% and Pi increased by 90% from hyperoxia values. During 60 min of hypoxia, the concentrations of high-energy phosphate metabolites did not change, but intracellular and arterial blood pH (pHa) decreased significantly. When hyperoxia was reestablished, pHi returned to normal and pHa remained low. These results suggest that during periods of hypoxemia, the normotensive infant rabbit maintains intracellular concentrations of cerebral high-energy phosphates better than has been reported for adult animals.
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PMID:Effects of hypoxic hypoxia on cerebral phosphate metabolites and pH in the anesthetized infant rabbit. 405 24

We analyzed brain tissue in 139 rats for adenosine and its metabolites, inosine and hypoxanthine, during the initial 120 seconds of seizures induced by bicuculline. We also measured ATP, ADP, AMP, phosphocreatine (PCr), and lactate. We divided the rats into four groups by adjustment of their preictal arterial oxygen tension: group I, PaO2 > 200 mm Hg; group II PaO2 = 50 mm Hg; and group III: PaO2 = 100 mm Hg. We treated a fourth group whose PaO2 = 100 mm Hg with phentolamine to block the 44% rise in blood pressure which occurred with the onset of seizures. PaCO2 was maintained between 30 anf 40 mm Hg in all groups. Brain tissue was sampled rapidly after 0, 10, 20, 30, 60, and 120 seconds of seizures by the freeze-blow technique. With normoxia (PaO2 = 100 mm Hg) or hyperoxia (PaO2 > 200 mm Hg), adenosine increased within ten seconds of the onset of seizures and remained elevated even after 120 seconds. Elevations in inosine and hypoxanthine were delayed compared to the increases in adenosine. A reduction in PaO2 (50 mm Hg) or systemic blood pressure during seizures caused a further augmentation in the increase in brain adenosine levels. During the seizure period, transient changes in adenine nucleotides and energy charge were observed, but PCr remained depressed and lactate continued to rise. The rapid and sustained increase in cerebral adenosine levels, temporally paralleling the changes in cerebral blood flow, supports the role for adenosine in the regulation of cerebral blood flow.
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PMID:Changes in brain adenosine during bicuculline-induced seizures in rats. Effects of hypoxia and altered systemic blood pressure. 677 98

Breathing of 100% oxygen at ambient pressure causes disorders in mouse brain organic phosphate phosphocreatine (PC), ATP, ADP, and AMP. The fast increase in PC level attains a maximum augmentation of about 50% after 16-18 h of exposure with subsequent slight alterations between 18 and 50 h. The initial losses (a) in ATP amount to approximately 20% after 4 h; (b) in ADP, 32% after 6-8 h; and (c) in AMP, about 40% after 30 min and 50% after 50 h. contrary to the continual decrease in AMP, the ATP and ADP values exhibit a later increase to a constant level during the full time of exposure up to 50 h. The initial loss in adenosine nucleotides points to an intense effect of hyperoxia in nerve cell metabolism with subsequent attainment of a new adenylate equilibrium at lower concentrations. The increased but constant level of PC may be due to an inhibition of the oxygen sensitive SH-groups, which are an essential center in the creatine kinase. Although the absolute concentration of AMP is by far the lowest of the three nucleotides, the continual decrease in AMP is of considerable importance because of its direct response to ATP via adenylate kinase reaction.
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PMID:Brain energy metabolism in mice exposed to oxygen at 1 atmosphere absolute. 733 82

In skeletal muscle, phosphocreatine (PCr) recovery from submaximal exercise has become a reliable and accepted measure of muscle oxidative capacity. During exercise, O2 availability plays a role in determining maximal oxidative metabolism, but the relationship between O2 availability and oxidative metabolism measured by 31P-magnetic resonance spectroscopy (MRS) during recovery from exercise has never been studied. We used 31P-MRS to study exercising human gastrocnemius muscle under conditions of varied fractions of inspired O2 (FIO2) to test the hypothesis that varied O2 availability modulates PCr recovery from submaximal exercise. Six male subjects performed three bouts of 5-min steady-state submaximal plantar flexion exercise followed by 5 min of recovery in a 1.5-T magnet while breathing three different FIO2 concentrations (0.10, 0. 21, and 1.00). Under each FIO2 treatment, the PCr recovery time constants were significantly different, being longer in hypoxia [33. 5 +/- 4.1 s (SE)] and shorter in hyperoxia (20.0 +/- 1.8 s) than in normoxia (25.0 +/- 2.7 s) (P </= 0.05). End-exercise pH was not significantly different among the three treatments (7.08 +/- 0.01 for 0.10, 7.04 +/- 0.01 for 0.21, and 7.04 +/- 0.02 for 1.00). These results demonstrate that PCr recovery is significantly altered by FIO2 and suggest that, after submaximal exercise, PCr recovery, under normoxic conditions, is limited by O2 availability.
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PMID:Skeletal muscle phosphocreatine recovery in exercise-trained humans is dependent on O2 availability. 1036 68

The hyperoxia-improved tolerance to maximal aerobic performance was studied in relation to exercising muscle metabolic state. Five students were submitted to four different tests on a cycle ergometer, each being conducted under normoxia and hyperoxia (60% FiO2) on separate days: Test 1, a progressive exercise until exhaustion to determine the maximal work load (Wmax) which was unchanged by hyperoxia; Test 2, an exercise at Wmax (287 +/- 12 W) until exhaustion to determine the performance time (texh) which was elevated by 38% under hyperoxia but exhaustion occurred at the same arterial proton and lactate concentrations; Test 3 (S-Exercise test) consisted of cycling at Wmax for 90% normoxic-texh (4.8 +/- 0.5 min under both O2 conditions) then followed by a 10-s sprint bout during which the total work output (Wtot) was determined; Wtot was elevated by 15% when exercising under hyperoxia; Test 4 (M-Exercise test) consisted also of cycling at Wmax for 4.8 +/- 0.5 min with blood and muscle samples taken at rest and at the end of the exercise to compare the level of different metabolites. During hyperoxic M-Exercise test, glycogen was twice more depleted whereas glucose-6-phosphate and lactate were less accumulated when compared with normoxia. No significant differences were observed for pyruvate, phosphocreatine and muscle/blood lactate ratio between the two conditions. Conversely to normoxia, levels of ATP, ADP and total NADH were maintained at their resting level under 60% FiO2. These data lead us to suppose a higher oxidation rate for pyruvate and NADH in mitochondria, thereby lowering the metabolic acidosis and allowing a better functioning of the glycolytic and contractile processes to delay the time to exhaustion.
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PMID:Effect of hyperoxia on aerobic and anaerobic performances and muscle metabolism during maximal cycling exercise. 1071 78

This study investigated whether increased muscle acetylcarnitine provision (acetate infusion) or hyperoxia (100% O(2)) would increase the rate of oxidative phosphorylation and reduce the reliance on muscle substrate phosphorylation after the onset of moderate exercise. Eight subjects completed three randomized trials, each separated by 1 wk: 1) saline infusion for 1 h before exercise, while breathing room air for 20 min before exercise and during 120 s of cycling at 65% maximal exercise (VO(2 max)) (CON), 2) saline infusion with 4 mmol/kg body wt sodium acetate, while breathing room air before and during exercise (ACE), and 3) saline infusion and breathing 100% O(2) before and during exercise (HYP). Muscle biopsies were sampled at rest and after 30 and 120 s of exercise. ACE increased muscle acetyl-CoA and acetylcarnitine contents at rest vs. CON and HYP [22.9 +/- 2.8 vs. 8.9 +/- 2.4 and 10.5 +/- 1.8 micromol/kg dry muscle (dm); 11.0 +/- 1.2 vs. 3.5 +/- 1.3 and 4.0 +/- 1.2 mmol/kg dm]. Acetate had no effect on resting pyruvate dehydrogenase activity in the active form (PDH(a)) among CON, ACE, and HYP. During exercise, acetyl-CoA and acetylcarnitine were unchanged in ACE but increased over time in the CON and HYP trials, and PDH(a) increased similarly in all trials. Muscle phosphocreatine use, lactate accumulation, and substrate phosphorylation energy provision after 30 or 120 s of exercise were similar in all trials. In summary, increased acetylcarnitine availability did not accelerate the rate of oxidative phosphorylation at the onset of exercise, suggesting that this is not a site of extra substrate. Hyperoxia had no effect on substrate phosphorylation, suggesting that O(2) availability does not limit oxidative phosphorylation at the onset of moderate exercise.
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PMID:Effects of acetate infusion and hyperoxia on muscle substrate phosphorylation after onset of moderate exercise. 1170 27

It is well established that altering O2 delivery to contracting skeletal muscle affects human performance. In this respect, a reduced O2 supply (e.g., hypoxia) increases the rate of muscle fatigue, whereas increasing O2 supply (e.g., hyperoxia) reduces the rate of fatigue. Interestingly, the faster onset of fatigue in moderate hypoxia does not appear to be a consequence of mitochondrial O2 limitation because these effects occur at submaximal rates of O2 consumption for these conditions and at O2 tensions well above that which impairs mitochondrial O2 uptake in vitro. Alterations in O2 supply modulate the regulation of cellular respiration and may affect the onset of impaired Ca2+ handling with fatigue. Specifically, changes in O2 supply alter the coupling between phosphocreatine hydrolysis and O2 uptake in contracting muscles, which by determining the rate of inorganic phosphate (Pi) accumulation may affect Ca2+ release. Partial ischemia differs somewhat in that the reduction in force could be due to reduced O2 supply and/or impaired removal of metabolic by-products secondary to insufficient blood flow. Nonetheless, recent evidence shows a parallel decline and restoration of force with alterations in O2 supply but not blood flow alone during submaximal contractions. Furthermore, the causes of fatigue are similar when O2 is plentiful and when it is reduced.
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PMID:The role of O2 supply in muscle fatigue. 1188 Jun 91

Previously, it was demonstrated in exercise-trained humans that phosphocreatine (PCr) recovery is significantly altered by fraction of inspired O2 (FI(O2)), suggesting that in this population under normoxic conditions, O2 availability limits maximal oxidative rate. Haseler LJ, Hogan ML, and Richardson RS. J Appl Physiol 86: 2013-2018, 1999. To further elucidate these population-specific limitations to metabolic rate, we used 31P-magnetic resonance spectroscopy to study the exercising human gastrocnemius muscle under conditions of varied FI(O2) in sedentary subjects. To test the hypothesis that PCr recovery from submaximal exercise in sedentary subjects is not limited by O2 availability, but rather by their mitochondrial capacity, six sedentary subjects performed three bouts of 6-min steady-state submaximal plantar flexion exercise followed by 5 min of recovery while breathing three different FI(O2) (0.10, 0.21, and 1.00). PCr recovery time constants were significantly longer in hypoxia (47.0 +/- 3.2 s), but there was no difference between hyperoxia (31.8 +/- 1.9 s) and normoxia (30.0 +/- 2.1 s) (mean +/- SE). End-exercise pH was not significantly different across treatments. These results suggest that the maximal muscle oxidative rate of these sedentary subjects, unlike their exercise-trained counterparts, is limited by mitochondrial capacity and not O2 availability in normoxia. Additionally, the significant elongation of PCr recovery in these subjects in hypoxia illustrates the reliance on O2 supply at the other end of the O2 availability spectrum in both sedentary and active populations.
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PMID:Skeletal muscle oxidative metabolism in sedentary humans: 31P-MRS assessment of O2 supply and demand limitations. 1513 10

This study compared the effects of inspiring either a hyperoxic (60% O(2)) or normoxic gas (21% O(2)) while cycling at 70% peak O(2) uptake on 1) the ATP derived from substrate phosphorylation during the initial minute of exercise, as estimated from phosphocreatine degradation and lactate accumulation, and 2) the reliance on carbohydrate utilization and oxidation during steady-state cycling, as estimated from net muscle glycogen use and the activity of pyruvate dehydrogenase (PDH) in the active form (PDH(a)), respectively. We hypothesized that 60% O(2) would decrease substrate phosphorylation at the onset of exercise and that it would not affect steady-state exercise PDH activity, and therefore muscle carbohydrate oxidation would be unaltered. Ten active male subjects cycled for 15 min on two occasions while inspiring 21% or 60% O(2), balance N(2). Blood was obtained throughout and skeletal muscle biopsies were sampled at rest and 1 and 15 min of exercise in each trial. The ATP derived from substrate-level phosphorylation during the initial minute of exercise was unaffected by hyperoxia (21%: 52.2 +/- 11.1; 60%: 54.0 +/- 9.5 mmol ATP/kg dry wt). Net glycogen breakdown during 15 min of cycling was reduced during the 60% O(2) trial vs. 21% O(2) (192.7 +/- 25.3 vs. 138.6 +/- 16.8 mmol glycosyl units/kg dry wt). Hyperoxia had no effect on PDH(a), because it was similar to the 21% O(2) trial at rest and during exercise (21%: 2.20 +/- 0.26; 60%: 2.25 +/- 0.30 mmol.kg wet wt(-1).min(-1)). Blood lactate was lower (6.4 +/- 1.0 vs. 8.9 +/- 1.0 mM) at 15 min of exercise and net muscle lactate accumulation was reduced from 1 to 15 min of exercise in the 60% O(2) trial compared with 21% (8.6 +/- 5.1 vs. 27.3 +/- 5.8 mmol/kg dry wt). We concluded that O(2) availability did not limit oxidative phosphorylation in the initial minute of the normoxic trial, because substrate phosphorylation was unaffected by hyperoxia. Muscle glycogenolysis was reduced by hyperoxia during steady-state exercise, but carbohydrate oxidation (PDH(a)) was unaffected. This closer match between pyruvate production and oxidation during hyperoxia resulted in decreased muscle and blood lactate accumulation. The mechanism responsible for the decreased muscle glycogenolysis during hyperoxia in the present study is not clear.
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PMID:Effects of hyperoxia on skeletal muscle carbohydrate metabolism during transient and steady-state exercise. 1537 50

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