UMLS:C0020440 - FACTA Search

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Query: UMLS:C0020440 (hypercapnia)
7,939 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To study the role of carbonic anhydrase in the CSF [HCO3] increase in respiratory acidosis and its effect on brain ammonia, anesthetized rats were subjected to hypercapnia (7% CO2) for 2 hours. The animals received periodic intraventricular injections of either 'mock' CSF or 'mock' CSF and acetazolamide for 45 minutes prior and during hypercapnia when: (a) plasma [HCO3-] was allowed to increase normally and (2) plasma [HCO3] increase was prevented by i.v. HC1 infusion, CSF [HCO3] increased 8.5 mM/L after 2 hours of hypercapnia (delta PCO2 40) in the rats with intraventricular 'mock' CSF injections, and only 6 mM/L in the animals with acetazolamide injections. CSF [HCO3-] increased 7 mM/L during hypercapnia and HCl infusion with intraventricular 'mock' CSF injections, but only 2 mM/L with acetazolamide injections. Changes in total brain CO2 (increase) and brain glutamic acid (decrease) in hypercapnia were not affected by intraventricular acetazolamide and i.v. HCl. The increase of brain NH4+ and glutamine in hypercapnia was reduced in these conditions. It is concluded that there are at least two sources for the CSF [HCO3-] increase in hypercapnia; one formed in the CNS and dependent on carbonic anhydrase, and the other derived from plasma [HCO3-] increase.
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PMID:The CSF HCO3 increase in hypercapnia relationshp to HCO3, glutamate, glutamine and NH3 in brain. 1 66

The effects of induced hypo- and hypercapnia upon the rate of hydroxylation of tryptophan and tyrosine in the rat brain were studied by measuring the accumulation of 5-HTP and DOPA following administration of the aromatic L-aminoacid decarboxylase inhibitor 3-hydroxybenzylhydrazine HCl (NSD 1015). The results suggest that the hydroxylation of tryptophan varies directly with the tissue Po2. On the other hand, the hydroxylation of tyrosine did not show a simple relationship to Po2 but appeared to be influenced by pH changes.
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PMID:Effect of hypercapnia and hypocapnia on tryptophan and tyrosine hydroxylation in rat brain. 1 38

It is accepted that in hypercapnia the rise in cerebrospinal fluid bicarbonate concentration (CSF [HCO3-]) occurs because of local HCO3--generating mechanisms, dependent on carbonic anhydrase, as well as on diffusion of HCO3- from plasma. To investigate further the regulation of CSF [HCO3-], CSF HCO3- formation was studied under conditions of pure isocapnic CSF "metabolic" acidosis. In anesthetized normocapnic dogs CSF [HCO3-] was lowered to approximately 15 mmol/l by perfusing the brain ventricles with a low HCO3- solution for 45 min. In dogs with normal plasma [HCO3-], CSF [HCO3-] rose by approximately 7 mmol/l in 2 h after the end of the perfusion. Lowering plasma [HCO3-] to 10 mmol/l by infusing HCl, limited the CSF [HCO3-] rise to 2 mmol/l, indicating the importance of plasma HCO3- for the restoration of CSF [HCO3-]. The small and persistent rise of CSF [HCO3-] at low plasma [HCO3-] occurred against a concentration gradient with blood. Intraventricular injection of acetazolamide had no further effect on this small rise. It is concluded that under the conditions of our experiments the CSF [HCO3-] rise is significantly dependent on plasma [HCO3-] and the caronic anhydrase-dependent HCO3- generation in the CNS is less important.
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PMID:Restoration of CSF [HCO3-] after its experimental lowering in normocapnic conditions. 11 88

1. Blood pressure and pulse rate responses to intravenously (i.v.) administered nifedipine were studied in chloralose-anaesthetized rats subjected to hypoxaemia, hyperoxaemia, alkalosis, acidosis, hypocarbia with alkalosis, or hypercarbia with acidosis. 2. Ventilation with a gas mixture of 17% O2, 28% O2, or 23% O2 with 5% CO2 at a fixed stroke volume (10 mL/kg) and rate (80 strokes/min) induced hypoxaemia, hyperoxaemia or hypercarbia, respectively. Hypocarbia was induced by ventilation with 17% O2 at 160 strokes/min. Acidosis or alkalosis was produced by intravenous infusion of 1 mol/L HCl or 1 mol/L NaHCO3, respectively, in animals ventilated with room air. 3. There were significant decreases in blood pressure and pulse rate during acidosis, and increases in pulse rate during alkalosis and hypercarbia. No marked changes in these parameters were observed under the other experimental conditions. 4. The control animals showed a dose-dependent decrease in blood pressure without marked changes in pulse rate in response to nifedipine injection. 5. Significant reductions in the hypotensive effect of nifedipine were observed in rats subjected to alkalosis, acidosis, or hypercarbia. A similar tendency was also found during hypocarbia while the responses to nifedipine during hypoxaemia and hyperoxaemia were statistically the same as those in the controls. 6. It is concluded that alterations of blood pH reduce the hypotensive effect of nifedipine, and we suggest that blood pH changes probably play a more important role than PO2 or PCO2 abnormalities in altering the cardiovascular responses to nifedipine in hypoventilated or hyperventilated rats.
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PMID:Cardiovascular responses to nifedipine in anaesthetized rats with abnormal blood gas/pH levels. 190 87

The effects of acidosis and alkalosis on pulmonary gas exchange were studied in 32 pentobarbital sodium-anesthetized intact dogs after induction of oleic acid (0.06 ml/kg) pulmonary edema. Gas exchange was assessed at constant ventilation and constant cardiac output, by venous admixture calculations and by intrapulmonary shunt measurements using the sulfur hexafluoride (SF6) method. Metabolic acidosis (pH 7.20) and alkalosis (pH 7.60) were induced with HCl and Carbicarb (isosmolar Na2CO3 and NaHCO3), respectively. Hypercapnia was induced by adding inspiratory CO2, whereas pH was allowed to change (respiratory acidosis, pH 7.20) or maintained constant (isolated hypercapnia). Mean intrapulmonary shunt and pulmonary arterial minus wedge pressure difference, respectively, changed from 44 to 33% (P less than 0.05) and from 9 to 10 mmHg (P greater than 0.05) in metabolic acidosis, from 44 to 62% (P less than 0.001) and from 12 to 8 mmHg (P less than 0.01) in metabolic alkalosis, from 40 to 42% (P greater than 0.05) and from 13 to 16 mmHg (P less than 0.05) in respiratory acidosis, from 42 to 52% (P less than 0.05) and from 8 to 12 mmHg (P less than 0.01) in isolated hypercapnia. These results indicate that acidosis, alkalosis, and hypercapnia markedly influence pulmonary gas exchange and/or pulmonary hemodynamics in dogs with oleic acid pulmonary edema.
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PMID:Acid-base status affects gas exchange in canine oleic acid pulmonary edema. 201 14

1. The effects of hypoxaemia, hyperoxaemia, alkalosis, acidosis, hypocarbia with alkalosis or hypercarbia with acidosis on the blood pressure and pulse rate responses to verapamil were studied in chloralose-anaesthetized rats. 2. At a fixed stroke volume (10 mL/kg) and rate (80 strokes/min; except for the hypocarbic group at 160 strokes/min), hypoxaemia, hyperoxaemia, hypercarbia with acidosis, or hypocarbia with alkalosis was induced by artificial ventilation with gas mixtures containing 17% O2, 28% O2, 23% O2, with 5% CO2, or 17% O2, without CO2 respectively. Acidosis or alkalosis was produced by intravenous infusion of 1 mol/L HCl or 1 mol/L NaHCO3 respectively, in animals artificially ventilated with room air. 3. Changes in individual blood gas/pH parameters had no significant effect on blood pressure except for acidosis which caused a significant decrease. Effects on pulse rate were significant increases in the alkalosis and hypercarbia groups, decrease in the acidosis group, while in other conditions no significant changes were recorded. 4. In the controls, intravenous injections of verapamil 20-320 micrograms/kg caused dose-dependent increases in mean blood pressure, while effects on pulse rate were not marked. 5. The hypotensive responses to verapamil were significantly alleviated or enhanced in the presence of alkalosis or acidosis respectively. Verapamil also caused greater falls in pulse rate during acidosis. Effects of Po2 changes were not statistically significant. The influence of PCO2 changes remained unclear. 6. The present findings suggest that changes in blood pH may play a more important role than Po2 alterations in affecting the cardiovascular responses to verapamil in the presence of blood gas abnormalities.
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PMID:Effects of blood gas/pH abnormalities on the cardiovascular actions of verapamil in rats. 212 29

It is well known that brain pH changes rapidly in acute hypercapnia or hypocapnia. The effect of acute isocapnic metabolic acid-base change on brain pH is less certain. To study this problem, acute isocapnic metabolic acidosis was induced by HCl or lactic acid infusions in rats, and recovery from acidosis was accomplished by NaHCO3 infusion. Brain pH was measured by 31P-nuclear magnetic resonance. Despite decreases in blood pH of 0.34 and 0.36 units, respectively, in less than 1 h of acid infusion and rapid recovery during bicarbonate infusion, brain pH was unaffected (ranging between 7.08 and 7.11) and was uncorrelated with blood pH. The blood pH minus brain pH gradient was eliminated by the acidosis. By contrast, hypoxia-induced endogenous lactic acidosis lowered blood and brain pH equivalently, but the fall in brain pH preceded that in blood. During normoxic recovery, brain pH overshot and became alkaline when blood pH was still significantly reduced and blood lactate levels were markedly elevated. Presumably, this is due to stimulated active H+ transport. The results demonstrate that brain pH is affected differently in metabolic, respiratory, and endogenous acid-base disturbances. Thus brain pH cannot be predicted solely from blood pH values.
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PMID:Brain pH in acute isocapnic metabolic acidosis and hypoxia: a 31P-nuclear magnetic resonance study. 230 94

In helical strips of dog cerebral arteries contracted with K+ or prostaglandin F2 alpha, the increase in CO2 from 5 to 15% in the gas aerating the bathing media produced a persistent relaxation in association with a rise of PCO2 and a fall of pH and PO2. Elevation of the NaHCO3 concentration from 25 to 75 mM in the bathing media under hypercapnia almost reversed the arterial tone when the osmolarity was balanced; the pH was completely reversed, whereas PCO2 was maintained at the high level. When 50 mM NaHCO3 were applied to the hypercapnic media without having the osmolarity balanced, the arteries relaxed further. Infusions of the HCl solution lowered the pH and relaxed the arterial strips; however, such a relaxation was significantly less than that caused by hypercapnia-induced acidosis. Relaxant responses to hypercapnia were attenuated by treatment with ouabain but were not influenced by amiloride and superoxide dismutase or by removal of endothelium. Relaxations due to hypertonic NaHCO3 were abolished or reversed to contractions by ouabain and were reduced by treatment with amiloride. It may be concluded that the hypercapnia-induced cerebroarterial relaxation is associated mainly with a fall of extracellular pH and is mediated partly by an activation of the electrogenic Na+ pump. Cerebral vasodilatation by increased osmolarity with NaHCO3 appears to result from stimulated Na+-H+ exchange and activated Na+ pump.
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PMID:Mechanisms underlying response to hypercapnia and bicarbonate of isolated dog cerebral arteries. 250 29

Respiratory acid-base disorders elicit physiological responses that alter O2 delivery to various tissues. We have used a near infrared (NIR) optical technique to monitor cytochrome a,a3 oxidation state, tissue O2 store (relative hemoglobin plus myoglobin oxygenation), and regional blood volume in intact resting skeletal muscle during respiratory acid-base disturbances in anesthetized cats. Hypercapnic acidosis and hypocapnic alkalosis were produced in separate groups of animals by ventilation with increasing concentrations of CO2 (n = 13) or hyperventilation (n = 8). Respiratory acidosis decreased oxygen availability to hindlimb muscle while respiratory alkalosis did not change tissue oxygenation. Inspired CO2 progressively decreased muscle blood volume, cytochrome a,a3 oxidation level, and muscle oxygen store. These optical responses were greatly attenuated both by pre-treatment with bretylium and by hemorrhagic hypotension, suggesting mediation through sympathetic vasoconstriction. Metabolic acidosis, produced by intravenous HCl infusion (n = 8), did not reproduce the hindlimb optical responses mediated by CO2. These experiments demonstrate that hypercapnic acidosis significantly decreases oxygen supply to resting skeletal muscle in the anesthetized cat, probably via neuroregulatory responses to CO2 which do not depend on changes in arterial [H+] in the tested pH range.
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PMID:Skeletal muscle oxygen availability during respiratory acid-base disturbances in cats. 282 60

1. Interstitial pH (pHo) was measured with ion-selective microelectrodes in the fascia dentata of rats anaesthetized with urethane, while CO2 levels were controlled by varying pulmonary ventilation and CO2 content of inspired air. In the CA1 sector of hippocampal tissue slices in vitro pHo was similarly measured and altered by varying CO2 in the gas phase, or by adding HCl or NaOH to the artificial cerebrospinal fluid (ACSF) of the bath, or by changing the concentration of HCO3-. 2. Orthodromically evoked compound action potentials ('population spikes') were depressed in hypercapnia and increased in hypocapnia. In the fascia dentata of intact brains the population spike of the granule cells varied on average by more than 40% of control amplitude for each 0.1 change of pHo. In the CA1 zone of tissue slices in vitro, the change of population spike amplitude was approximately 30% per pH change of 0.1 caused by altered CO2 or HCO3- concentration, but only about 15% per pH change of 0.1 when HCl or NaOH were administered. 3. In anaesthetized rats the focal synaptic potential (FEPSP) evoked by a given stimulus intensity was weakly influenced by varying [CO2]; in tissue slices weak effects on FEPSP were inconsistent. In hippocampus both in situ and in vitro the population spike triggered by a given magnitude of FEPSP increased in hypocapnia and decreased in hypercapnia. This suggests that the main effect of CO2 is on the electric excitability of postsynaptic cells, with minor or no effect on transmitter release and on the interaction of the transmitter with its receptors. 4. Hypercapnia of anaesthetized rats was usually associated with a slight increase of [K+]o in the fascia dentata. Tissue [Ca2+]o changed little and not consistently. Neither of these two ions, nor concomitant changes of blood pressure or tissue partial pressure of oxygen, (Pt, O2), could account for the effects of pH on neuronal excitability. 5. The results show that increasing the extracellular concentration of H+ ions has a moderately depressant effect on the firing threshold of hippocampal neurones. The more powerful effects of elevated [CO2] and of lowered [HCO3-] may probably be explained by a direct effect on the neuronal membrane. The brain, by regulating breathing, controls its own excitability.
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PMID:Concentration of carbon dioxide, interstitial pH and synaptic transmission in hippocampal formation of the rat. 284 90

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