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

The carotid body (CB) chemoreceptors may play an important role in the enhanced hypoxic ventilatory response induced by chronic intermittent hypoxia (CIH). We studied the effects of cyclic hypoxic episodes of short duration on cat cardiorespiratory reflexes, heart rate variability, and CB chemosensory activity. Cats were exposed to cyclic hypoxic episodes (PO2 approximately 75 Torr) repeated during 8 h for 2-4 days. Cats were anaesthetized with sodium pentobarbitone (40 mg kg(-1) i.p., followed by 8-12 mg i.v.), and ventilatory and cardiovascular responses to NaCN (0.1-100 microg kg(-1) i.v.) and several isocapnic levels of oxygen (PO2 approximately 20-740 Torr) were studied. After studying the reflex responses, we recorded the CB chemosensory responses induced by the same stimuli. Results showed that CIH for 4 days selectively enhanced cat CB ventilatory (VT and VI) responses to hypoxia, while responses to NaCN remained largely unchanged. Similarly, basal CB discharges and responses to acute hypoxia (PO2 < 100 Torr) were larger in CIH than in control cats, without modification of the responses to NaCN. Exposure to CIH did not increase basal arterial pressure, heart rate, or their changes induced by acute hypoxia or hyperoxia. However, the spectral analysis of heart rate variability of CIH cats showed a marked increase of the low-/high-frequency ratio and an increase of the power spectral distribution of low frequencies of heart rate variability. Thus, the enhanced CB reactivity to hypoxia may contribute to the augmented ventilatory response to hypoxia, as well as to modified heart rate variability due to early changes in autonomic activity.
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PMID:Chronic intermittent hypoxia enhances cat chemosensory and ventilatory responses to hypoxia. 1531 19

This study examined the effect of acute hypoxic and hypercapnic cardiorespiratory stimuli, superimposed on existing cardiorespiratory disturbances in tambaqui. In their natural habitat, these fish often encounter periods of hypoxic hypercapnia that can be acutely exacerbated by water turnover. Tambaqui were exposed to periods of normoxia, hypoxia, hyperoxia and hypercapnia during which, externally oriented O2 and CO2 chemoreceptors were further stimulated, by administration into the inspired water of sodium cyanide and CO2-equilibrated water, respectively. Hyperoxic water increased the sensitivity of the NaCN-evoked increase in breathing frequency (f(R)) and decrease in heart rate. Hypoxia and hypercapnia attenuated the increase in f(R) but, aside from blood pressure, did not influence the magnitude of NaCN-evoked cardiovascular changes. Water PO2 influenced the magnitude of the CO2-evoked cardiorespiratory changes and the sensitivity of CO2-evoked changes in heart rate and blood flow. The results indicate that existing respiratory disturbances modulate cardiorespiratory responses to further respiratory challenges reflecting both changes in chemosensitivity and the capacity for further change.
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PMID:Reciprocal modulation of O2 and CO2 cardiorespiratory chemoreflexes in the tambaqui. 1576 6

Adult rats have decreased carotid body volume and reduced carotid sinus nerve, phrenic nerve, and ventilatory responses to acute hypoxic stimulation after exposure to postnatal hyperoxia (60% O2, PNH) during the first 4 weeks of life. Moreover, sustained hypoxic exposure (12%, 7 days) partially reverses functional impairment of the acute hypoxic phrenic nerve response in these rats. Similarly, 2 weeks of PNH results in the same phenomena as above except that ventilatory responses to acute hypoxia have not been measured in awake rats. Thus, we hypothesized that 2-week PNH-treated rats would also exhibit blunted chemoafferent responses to acute hypoxia, but would exhibit ventilatory acclimatization to sustained hypoxia. Rats were born into, and exposed to PNH for 2 weeks, followed by chronic room-air exposure. At 3-4 months of age, two studies were performed to assess: (1) carotid sinus nerve responses to asphyxia and sodium cyanide in anesthetized rats and (2) ventilatory and blood gas responses in awake rats before (d0), during (d1 and d7), and 1 day following (d8) sustained hypoxia. Carotid sinus nerve responses to i.v. NaCN and asphyxia (10 s) were significantly reduced in PNH-treated versus control rats; however, neither the acute hypoxic ventilatory response nor the time course or magnitude of ventilatory acclimatization differed between PNH and control rats despite similar levels of PaO2 . Although carotid body volume was reduced in PNH rats, carotid body volumes increased during sustained hypoxia in both PNH and control rats. We conclude that normal acute and chronic ventilatory responses are related to retained (though impaired) carotid body chemoafferent function combined with central neural mechanisms which may include brainstem hypoxia-sensitive neurons and/or brainstem integrative plasticity relating both central and peripheral inputs.
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PMID:Carotid sinus nerve responses and ventilatory acclimatization to hypoxia in adult rats following 2 weeks of postnatal hyperoxia. 1597 76

Benefits from an antihypoxic agent (sodium oxibutyrate) and normal pressure hyperoxia to the lipid composition of erythrocyte membranes and blood plasma were assessed in 9 subjects on the thirtieth day of head-down tilting at -8(0). The greatest variations in HDT occurred in polyunsaturated fatty acids in erythrocyte membranes. After infusion of sodium oxibutyrate a marked reduction in polyunsaturated fatty acids was mainly in consequence of expressed decreases in linoleic and, particularly, arachidonic acids. However, ensuing hyperoxic treatment led to their steady rise. Sequential sodium oxibutyrate infusion to the tilted subjects breathing air and then exposed to normal pressure hyperoxia seemed to have compensated, as judged by the fatty acids in erythrocyte membranes, for the activity of free radical oxidation in hypoperfusated regional tissues.
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PMID:[Assessment of the effects of sodium oxybutyrate and normal pressure hyperoxia on human blood plasma and erythrocyte membrane lipids during antiorthostatic hypokinesia]. 1607 23

The goals of this study were to assess the respiratory consequences of exposing adult zebrafish Danio rerio to chronic changes in water gas composition (hypoxia, hyperoxia or hypercapnia) and to determine if any ensuing effects could be related to morphological changes in branchial chemoreceptors. To accomplish these goals, we first modified and validated an established non-invasive technique for continuous monitoring of breathing frequency and relative breathing amplitude in adult fish. Under normal conditions 20% of zebrafish exhibited an episodic breathing pattern that was composed of breathing and non-breathing (pausing/apneic) periods. The pausing frequency was reduced by acute hypoxia (Pw(O)2<130 mmHg) and increased by acute hyperoxia (Pw(O)2>300 mmHg), but was unaltered by acute hypercapnia. Fish were exposed for 28 days to hyperoxia (Pw(O)2>350 mmHg), or hypoxia (Pw(O)2=30 mmHg) or hypercapnia (Pw(CO)2=9 mmHg). Their responses to acute hypoxia or hypercapnia were then compared to the response of control fish kept for 28 days in normoxic and normocapnic water. In control fish, the ventilatory response to acute hypoxia consisted of an increase in breathing frequency while the response to acute hypercapnia was an increase in relative breathing amplitude. The stimulus promoting the hyperventilation during hypercapnia was increased Pw(CO)2 rather than decreased pH. Exposure to prolonged hyperoxia decreased the capacity of fish to increase breathing frequency during hypoxia and prevented the usual increase in breathing amplitude during acute hypercapnia. In fish previously exposed to hyperoxia, episodic breathing continued during acute hypoxia until Pw(O)2 had fallen below 70 mmHg. In fish chronically exposed to hypoxia, resting breathing frequency was significantly reduced (from 191+/-12 to 165+/-16 min(-1)); however, the ventilatory responses to hypoxia and hypercapnia were unaffected. Long-term exposure of fish to hypercapnic water did not markedly modify the breathing response to acute hypoxia and modestly blunted the response to hypercapnia. To determine whether branchial chemoreceptors were being influenced by long-term acclimation, all four groups of fish were acutely exposed to increasing doses of the O(2) chemoreceptor stimulant, sodium cyanide, dissolved in inspired water. Consistent with the blunting of the ventilatory response to hypoxia, the fish pre-exposed to hyperoxia also exhibited a blunted response to NaCN. Pre-exposure to hypoxia was without effect whereas prior exposure to hypercapnia increased the ventilatory responses to cyanide. To assess the impact of acclimation to varying gas levels on branchial O(2) chemoreceptors, the numbers of neuroepithelial cells (NECs) of the gill filament were quantified using confocal immunofluorescence microscopy. Consistent with the blunting of reflex ventilatory responses, fish exposed to chronic hyperoxia exhibited a significant decrease in the density of NECs from 36.8+/-2.8 to 22.7+/-2.3 filament(-1).
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PMID:Chemoreceptor plasticity and respiratory acclimation in the zebrafish Danio rerio. 1654 98

Cleft lip (CL) is a common malformation that has both genetic and exogenous causes. The main pharmaceutical cause is exposure to phenytoin during early facial development in the 5th to 6th weeks of gestation. Phenytoin also causes CL if administered to pregnant rats during the period of early facial development. Evidence is presented that in the pregnant rat, a teratogenic dose of phenytoin slows the early embryonic heart and causes a prolonged period of embryonic hypoxia. It is proposed that this hypoxia, through an undefined downstream mechanism, leads to the development of CL. The involvement of hypoxia in the pathogenesis of CL is in agreement with studies in mouse strains with a spontaneous rate of CL in which exposure to hypoxia has been shown to increase the rate and hyperoxia to decrease the rate. Other exogenous risk factors during pregnancy for human CL include maternal cigarette smoking, residence at high altitude and exposure to corticosteroids. It is suggested that these exposures all involve an increased risk of embryonic hypoxia. It has been proposed that phenytoin affects the embryonic heart by inhibition of the human-ether-a-go-go (HERG) potassium channel. Phenytoin also inhibits sodium and calcium channels and these properties may also be involved in the observed effect on the embryonic heart. Phenytoin-induced bradycardia leading to embryonic hypoxia may be an important mechanism by which phenytoin causes birth defects.
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PMID:The relationship between cleft lip, maxillary hypoplasia, hypoxia and phenytoin. 1661 Nov 27

The influence of hyperoxia on the cutaneous vasodilator responses to iontophoretic applications of acetylcholine (ACh) and sodium nitroprusside (SNP) was examined in healthy subjects. The breathing of 100% O(2) decreased (P < 0.05) the vasodilator response to Ach, but not to SNP, suggesting that hyperoxia attenuates endothelial-mediated vasodilation of the human skin.
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PMID:Hyperoxia attenuates endothelial-mediated vasodilation in the human skin. 1716 68

Renal blood flow (RBF) can be reduced in rats and rabbits by up to 40% without significant changes in renal tissue Po(2). We determined whether this occurs because renal oxygen consumption changes with RBF or due to some other mechanism. The relationships between RBF and renal cortical and medullary tissue P(O(2)) and renal oxygen metabolism were determined in the denervated kidneys of anesthetized rabbits under hypoxic, normoxic, and hyperoxic conditions. During artificial ventilation with 21% oxygen (normoxia), RBF increased 32 +/- 8% during renal arterial infusion of acetylcholine and reduced 31 +/- 5% during ANG II infusion. Neither infusion significantly altered arterial pressure, tissue P(O(2)) in the renal cortex or medulla, nor renal oxygen consumption. However, fractional oxygen extraction fell as RBF increased and the ratio of oxygen consumption to sodium reabsorption increased during ANG II infusion. Ventilation with 10% oxygen (hypoxia) significantly reduced both cortical and medullary P(O(2)) (60-70%), whereas ventilation with 50% and 100% oxygen (hyperoxia) increased cortical and medullary P(O(2)) (by 62-298 and 30-56%, respectively). However, responses to altered RBF under hypoxic and hyperoxic conditions were similar to those under normoxic conditions. Thus renal tissue P(O(2)) was relatively independent of RBF within a physiological range (+/-30%). This was not due to RBF-dependent changes in renal oxygen consumption. The observation that fractional extraction of oxygen fell with increased RBF, yet renal parenchymal P(O(2)) remained unchanged, supports the hypothesis that preglomerular diffusional shunting of oxygen from arteries to veins increases with increasing RBF, and so contributes to dynamic regulation of intrarenal oxygenation.
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PMID:Evidence that renal arterial-venous oxygen shunting contributes to dynamic regulation of renal oxygenation. 1732 97

The kidney is faced with unique challenges for oxygen regulation, both because its function requires that perfusion greatly exceeds that required to meet metabolic demand and because vascular control in the kidney is dominated by mechanisms that regulate glomerular filtration and tubular reabsorption. Because tubular sodium reabsorption accounts for most oxygen consumption (Vo2) in the kidney, renal Vo2 varies with glomerular filtration rate. This provides an intrinsic mechanism to match changes in oxygen delivery due to changes in renal blood flow (RBF) with changes in oxygen demand. Renal Vo2 is low relative to supply of oxygen, but diffusional arterial-to-venous (AV) oxygen shunting provides a mechanism by which oxygen superfluous to metabolic demand can bypass the renal microcirculation. This mechanism prevents development of tissue hyperoxia and subsequent tissue oxidation that would otherwise result from the mismatch between renal Vo2 and RBF. Recent evidence suggests that RBF-dependent changes in AV oxygen shunting may also help maintain stable tissue oxygen tension when RBF changes within the physiological range. However, AV oxygen shunting also renders the kidney susceptible to hypoxia. Given that tissue hypoxia is a hallmark of both acute renal injury and chronic renal disease, understanding the causes of tissue hypoxia is of great clinical importance. The simplistic paradigm of oxygenation depending only on the balance between local perfusion and Vo2 is inadequate to achieve this goal. To fully understand the control of renal oxygenation, we must consider a triad of factors that regulate intrarenal oxygenation: local perfusion, local Vo2, and AV oxygen shunting.
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PMID:Intrarenal oxygenation: unique challenges and the biophysical basis of homeostasis. 1855 Jun 45

Long-term vascular and renal consequences of neonatal oxidative injury are unknown. Using a rat model, we sought to investigate whether vascular function and blood pressure are altered in adult rats exposed to hyperoxic conditions as neonates. We also questioned whether neonatal O(2) injury causes long-term renal damage, important in the pathogenesis of hypertension. Sprague-Dawley pups were kept with their mother in 80% O(2) or room air from days 3 to 10 postnatal, and blood pressure was measured (tail cuff) from weeks 7 to 15. Rats were euthanized, and vascular reactivity (ex vivo carotid rings), oxidative stress (lucigenin chemiluminescence and dihydroethidium fluorescence), microvascular density (tibialis anterior muscle), and nephron count were studied. In male and female rats exposed to O(2) as newborns, systolic and diastolic blood pressures were increased (by an average of 15 mm Hg); ex vivo, maximal vasoconstriction (both genders) and sensitivity (males only) specific to angiotensin II were increased; endothelium-dependant vasodilatation to carbachol but not to NO-donor sodium nitroprussiate was impaired; superoxide dismutase analogue prevented vascular dysfunction to angiotensin II and carbachol; vascular superoxide production was higher; and capillary density (by 30%) and number of nephrons per kidney (by 25%) were decreased. These data suggest that neonatal hyperoxia leads in the adult rat to increased blood pressure, vascular dysfunction, microvascular rarefaction, and reduced nephron number in both genders. Our findings support the hypothesis of developmental programming of adult cardiovascular and renal diseases and provide new insights into the potential role of oxidative stress in this process.
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PMID:Neonatal oxygen exposure in rats leads to cardiovascular and renal alterations in adulthood. 1885 82


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