Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0242706 (hyperoxia)
5,219 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To determine whether platelet activating factor (PAF) plays a role in the responses seen in the fetal and transitional circulations, we assessed endogenous release of PAF in cultured fetal ovine endothelial cells from the pulmonary artery (PA), ductus arteriosus (DA) and aorta (Ao) under basal conditions and following exposure to hypoxia or hyperoxia. The cells were prelabeled with [3H] acetate and subsequently exposed to different ambient oxygen concentrations, i.e., 95% O2 or 95% N2, balance CO2, using calcium ionophore as a positive control. The effect of indomethacin on DA endothelial PAF production following stimulation with ionophore was also established. Synthesis of [3H] PAF was measured by counts comigrating on TLC with unlabeled PAF. We found that PAF production by fetal ovine PA, Ao and DA cells was similar and unaffected by hypoxia or hyperoxia. Exposure of ionophore stimulated DA cells to indomethacin was, however, associated with a decrease in PAF production (p less than 0.05). We speculate that in vitro alterations in ambient O2 concentration do not influence fetal ovine endothelial PAF production but indomethacin may decrease PAF production in the DA.
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PMID:Effect of ambient oxygen changes on platelet activating factor production by fetal ovine endothelial cells. 186 26

Steady-state CO2-ventilation response curves with hyperoxia (end-tidal PO2 greater than 200 Torr) and mild hypoxia (end-tidal PO2 approximately equal to 60 Torr) were compared in five carotid body-resected (BR) patients and five control patients. The data were analyzed by fitting a linear equation, V = S(PETCO2-B), where V is minute ventilation S is the response curve slope. PETCO2 is end-tidal PCO2, and B is the response curve threshold. S slightly increased from hyperoxia to hypoxia in both BR and control groups. On the other hand, B moderately increased with hypoxia in BR patients, whereas it slightly decreased in controls. These changes were all not significant. However, in accordance with the change in B, the response curve to hypoxia at V of 10 1/min was significantly shifted in opposite directions in the two groups, i.e., rightward and leftward shift in BR and control groups, respectively. Thus the average magnitude of V calculated at PETCO2 of 40 Torr in hypoxia was significantly lower in BR patients than in controls (P less than 0.01). We conclude that this hypoxic depression of the CO2-ventilation response found in BR patients may have resulted, at least in part, from modulation of the brain stem neural mechanisms that were elicited by loss of afferent discharges from the carotid body.
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PMID:Evidence for hypoxic depression of CO2-ventilation response in carotid body-resected humans. 190 55

We have studied the mode of ventilation and chemosentivity in 10 patients suffering from pulmonary fibrosis. The total lung capacity was on average 63.5 +/- 8% of the predicted. Their static compliance was 0.078 +/- 0.05 l.cm of water. The patients were studied in the prone position breathing ambient air then on hyperoxia. The response to CO2 was assessed according to the rebreathing method of Read. The results of these patients were compared with those of 11 normal subjects. The ventilation at rest was normal, with a shortened respiratory time and a Ti/Ttot ratio which was lowered. The occlusion pressure (P0.1) was very much higher than that in normal subjects. This rise was correlated with an increase in pulmonary elastance and a reduction in vital capacity. The correction of hypoxia was without effect on the respiratory parameters. In relation to normal subjects the ventilatory response to carbon dioxide in fibrotics was decreased whilst the response of the P0.1 was increased expressing central hyperactivity. In conclusion, fibrotic patients have normal ventilation in spite of an increase in inspiratory work. This normal ventilation results from hyperactivity of the respiratory centre, as in the hyperventilation induced by carbon dioxide when at rest.
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PMID:[The control of respiration in pulmonary fibrosis. The effect of O2 and CO2]. 190 51

We investigated the mechanisms responsible for oxygen-induced hypercarbia in ventilator-dependent patients with advanced chronic obstructive pulmonary disease (COPD). To quantitate the effects of oxygen (O2) on respiratory drive, we determined the CO2 recruitment threshold (PCO2 RT) in 10 mechanically ventilated patients under normoxic (PaO2 = 67 +/- 7 mm Hg) and hyperoxic (PaO2 = 370 +/- 67 mm Hg) conditions. PCO2 RT is a measure of the CO2 responsiveness of the mechanically unloaded respiratory system and, as such, is independent of mechanical impedance and respiratory muscle strength. After O2 supplementation, PCO2 RT increased from 42 +/- 6 to 45 +/- 6 mm Hg (p less than or equal to 0.05), indicating a suppression of so-called hypoxic respiratory drive. The effect of hyperoxia on the dead space to tidal volume ratio (VD/VT) and CO2 elimination (VCO2) was studied in 6 patients. Measurements were made at identical ventilator settings, thus eliminating breathing pattern- and respiratory work-related effects on these variables. VD/VT rose from 0.49 +/- 0.09 to 0.55 +/- 0.06 (p less than or equal to 0.05), but VCO2 remained constant at 0.21 L/min. We discuss why measuring O2-induced changes in minute ventilation, VCO2, PaO2, and VD/VT in spontaneously breathing patients is insufficient to distinguish between gas exchange- and respiratory drive-related mechanisms for hypercarbia. Based on the O2-induced increase in PCO2 RT, we conclude that so-called suppression of hypoxic drive plays an important role in the pathogenesis of this disorder.
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PMID:Oxygen-induced hypercarbia in obstructive pulmonary disease. 190 46

The effect of tumor necrosis factor-alpha (TNF) on hyperoxia-induced endothelial injury in vitro was investigated. TNF caused a time- and dose-dependent reduction in the number of viable pulmonary artery endothelial cells. The TNF-mediated endothelial cytotoxicity was more pronounced under hyperoxia (95% O2 and 5% CO2) than under normoxia (95% air and 5% CO2). Pretreatment of endothelial cells with TNF (0.01 micrograms/ml or 240 U/ml) for 18 h at normoxia reduced the intracellular concentration of total glutathione (GSH), whereas the concentration of oxidized GSH was increased. These TNF-treated endothelial cells were more susceptible to hyperoxia- or hydrogen peroxide-mediated cytotoxicity. TNF also induced changes in endothelial morphology and in the distribution and density of actin filaments. Exogenous GSH or L-2-oxothiazolidine-4-carboxylate, which enhanced endothelial GSH concentrations, partially protected endothelial cells against TNF-mediated cytotoxicity, morphologic changes, and actin filament redistribution, especially under the hyperoxic condition. These results suggest an important role of GSH in modulating endothelial response to TNF.
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PMID:Tumor necrosis factor enhances endothelial cell susceptibility to oxygen toxicity: role of glutathione. 195 83

The primary aim of this study was to determine the influence of systemic hyperoxia on sympathetic nervous system behavior at rest and during submaximal exercise in humans. In seven healthy subjects (aged 19-31 yr) we measured postganglionic sympathetic nerve activity to skeletal muscle (MSNA) in the leg, antecubital venous norepinephrine concentrations, heart rate, and arterial blood pressure during normoxic rest (control) followed by 3- to 4-min periods of either hyperoxic (100% O2 breathing) rest, normoxic exercise (rhythmic handgrips at 50% of maximum force), or hyperoxic exercise. During exercise, isocapnia was maintained by adding CO2 to the inspirate as necessary. At rest, hyperoxia lowered MSNA burst frequency (12-42%) and total activity (6-42%) in all subjects; the average reductions were 25 and 23%, respectively (P less than 0.05 vs. control). Heart rate also decreased during hyperoxia (6 +/- 1 beats/min, P less than 0.05), but arterial blood pressure was not affected. During hyperoxic compared with normoxic exercise, there were no differences in the magnitudes of the increases in MSNA burst frequency or total activity, plasma norepinephrine concentrations, or mean arterial blood pressure. In contrast, the increase in heart rate during hyperoxic exercise (13 +/- 2 beats/min) was less than the increase during normoxic exercise (20 +/- 2 beats/min; P less than 0.05). We conclude that, in healthy humans, systemic hyperoxia 1) lowers efferent sympathetic nerve activity to skeletal muscle under resting conditions without altering venous norepinephrine concentrations and 2) has no obvious modulatory effect on the nonactive muscle sympathetic nerve adjustments to rhythmic exercise.
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PMID:Hyperoxia lowers sympathetic activity at rest but not during exercise in humans. 203 99

Almitrine has potential as a tool for testing the physiological role of the peripheral chemoreceptor. The effects of almitrine on CO2 chemosensitivity were studied at rest and during light exercise using a constant inflow technique that avoids the hyperoxia of rebreathing methods. The steady-state ventilatory response to CO2 was measured in two groups of six normal men before and 150 min after 100 mg oral almitrine bismesylate or placebo. One group was studied at rest, the other while pedalling at 50 W. The resting group showed a significant increase in CO2 response slope after almitrine when compared with placebo but there was no significant change in the response intercept. During exercise the individual results were very variable and after almitrine no significant change was seen in either the response slope or intercept. Control ventilation was not affected by almitrine in either group. Even in the absence of marked hyperoxia the effect of almitrine on CO2 sensitivity at rest in small. The lack of effect at 50 W is against any important role for the peripheral chemoreceptor during light exercise but other interpretations are possible.
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PMID:The effect of almitrine on the steady-state ventilatory response to carbon dioxide at rest and during exercise in man. 211 16

1. The ventilatory sensitivity to carbon dioxide obtained from a step-ramp CO2 challenge was compared to the CO2 sensitivity from the steady-state method. 2. Experiments were performed in nine healthy male subjects against a background of hyperoxia and in two subjects against a background of normoxia. 3. In each subject experiments were performed in which the stepwise increase in end-tidal PCO2 above its resting value (A) was varied (range 0-2 kPa) and the subsequent rate of rise of end-tidal PCO2 in time (R) kept constant at 0.6 or 0.8 kPa min-1. 4. The results of the hyperoxic experiments show that the slope of the non-steady-state ventilatory response to CO2 (Sn) is greatly influenced by the magnitude of A. An increase of A of 1 kPa results in a 54% increase of the ratio non-steady-state ventilatory CO2 sensitivity to steady-state ventilatory CO2 sensitivity (Ss). The magnitude of R plays a minor role in determining Sn. The normoxic experiments gave similar results. 5. In experiments performed during hyperoxia Sn approximates Ss when the magnitude of A is 0.5 kPa. 6. The results are discussed and related to a physiological model. Simulations with representative values for the model parameters are in fair agreement with experimental values.
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PMID:On a pseudo-rebreathing technique to assess the ventilatory sensitivity to carbon dioxide in man. 211 56

1. The ventilatory response to isoxic square-wave challenges in end-tidal PCO2 was investigated at three levels of end-tidal PO2 (PET, O2) in nine healthy male subjects. 2. Twenty-seven responses against a background of mild hypoxia (PET, O2 approximately 10 kPa), sixty-seven against a background of normoxia (PET, O2 approximately 14.5 kPa) and seventy-six against a background of hyperoxia (PET, O2 approximately 70 kPa) were collected. 3. The breath-to-breath data were partitioned into a fast and a slow ventilatory component using a two-compartment model. 4. In the normoxic and hypoxic experiments the CO2 sensitivity of the fast component averaged to about 30 and 40% of the total CO2 sensitivity, respectively. In the hyperoxic experiments three subjects had no fast component in their response while in three others the CO2 sensitivity of the fast component averaged to about 24% of the total CO2 sensitivity. In the remaining three subjects the presence of a fast component was doubtful. 5. We argue that the fast component is due to the peripheral chemoreflex loop and the slow component to the central chemoreflex loop. 6. The central CO2 sensitivity and the apnoeic threshold (extrapolated end-tidal CO2 at zero ventilation in the steady state) were 15% smaller in hyperoxia than those in normoxia and hypoxia. In normoxia and mild hypoxia the central CO2 sensitivities were not significantly different. 7. We argue, that apart from peripheral oxygen-carbon dioxide interaction, there is evidence for central oxygen-carbon dioxide interaction in human subjects. 8. We conclude that in general there is a contribution to ventilation of the peripheral chemoreceptors during hyperoxia in man.
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PMID:The influence of oxygen on the ventilatory response to carbon dioxide in man. 212 61

After voluntary hyperventilation, normal humans do not develop a significant ventilatory depression despite low arterial CO2 tension, a phenomenon attributed to activation of a brain stem mechanism referred to as the "afterdischarge." Afterdischarge is one of the factors that promote ventilatory stability. It is not known whether physiological stimuli, such as hypoxia, are able to activate the afterdischarge in humans. To test this, breath-by-breath ventilation (VI) was measured in nine young adults during and immediately after a brief period (35-51 s) of acute hypoxia (end-tidal O2 tension 55 Torr). Hypoxia was terminated by switching to 100% O2 (end-tidal O2 tension of first posthypoxic breath greater than 100 Torr). Brief hypoxia increased VI and decreased end-tidal CO2 tension. In all subjects, termination of hypoxia was followed by a gradual ventilatory decay; hyperoxic VI remained higher than the normoxic baseline for several breaths and, despite the negative chemical stimulus of hyperoxia and hypocapnia, reached a new steady state without an apparent undershoot. We conclude that brief hypoxia is able to activate the afterdischarge mechanism in conscious humans. This contrasts sharply with the ventilatory undershoot that follows relief of sustained hypoxia, thereby suggesting that sustained hypoxia inactivates the afterdischarge mechanism. The present findings are of relevance to the pathogenesis of periodic breathing in a hypoxic environment. Furthermore, brief exposure to hypoxia might be useful for evaluation of the role of afterdischarge in other disorders associated with unstable breathing.
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PMID:Hypoxic exposure and activation of the afterdischarge mechanism in conscious humans. 212 78


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