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

Neotenic larval Ambystoma tigrinum were subjected to hypercapnia (3% CO2, 22 Torr) for 24 h under different conditions: alpha-adrenergic blockade using phentolamine, beta-adrenergic blockade using propranolol, and sham treatments. The sham animals were able to carry out a partial extracellular pH compensation that consisted of an increase in extracellular [HCO3-]. Animals treated with catecholamine antagonists did not compensate to the same extent. Analysis of plasma samples by high-performance liquid chromatography with electrochemical detection revealed a significant increase in circulating norepinephrine, but not epinephrine, during the high-CO2 exposure. Measurements of cutaneous ion transport showed that beta-antagonists block the increased Na+ influx associated with hypercapnia, whereas alpha-antagonists inhibited the decrease in cutaneous Cl- influx that is also associated with respiratory acidosis. Additionally, both alpha- and beta-blockers inhibited the increase in transcutaneous potential difference that accompanied the respiratory acidosis. The results are consistent with a role for circulating catecholamines in compensatory ion transport responses to respiratory acidosis in this species.
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PMID:Acid-base-electrolyte balance responses to catecholamine antagonists in Ambystoma tigrinum. 211 75

This study examined the possible role(s) of central acid-base stimuli in the increase in ventilation induced by hypercapnia in the skate, a response that is not due to an O2 signal (Graham et al., Respir. Physiol., 1990, 80: 251-270). Skate were sampled for cerebrospinal fluid (CSF) acid-base status, intracellular pH of the brain (14C-DMO method), and pHi in other tissues throughout 24 h of exposure to PICO2 = 7.5 Torr. CSF PCO2 rapidly equilibrated with the elevated PaCO2. Despite the much lower non-HCO3- buffer capacity in the CSF, CSF pH was not depressed to the same extent as blood pHa. CSF pH was also regulated rapidly, returning to control levels by 8-10 h, whereas pHa remained significantly depressed at 24 h. Similarly, the pHis of the weakly buffered brain and heart ventricle were initially compensated more rapidly than those of more strongly buffered white muscle and red blood cells. However, brain pHi adjustment slowed markedly after 4 h and stabilized at only 70% compensation by 20-24 h, suggesting that brain intracellular acidosis may play a role in the long-term increase in ventilation. CSF and brain were the only compartments which did not exhibit an apparent compounding metabolic acidosis during the initial stages of hypercapnic exposure. While these results illustrate the primacy of central acid-base regulation, they do not support a role for CSF pH in the long-term elevation of ventilation in response to hypercapnia. Depressions in pHa and brain pHi appear the two most likely candidates for proximate stimuli.
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PMID:Control of ventilation in the hypercapnic skate Raja ocellata: II. Cerebrospinal fluid and intracellular pH in the brain and other tissues. 212 Jul 54

In order to study the role of CO2 and acid-base status in contributing to ventilatory drive, skate were exposed to normoxic hypercapnia (PICO2 = 7.5 Torr) under conditions where the primary O2 drive would remain unaltered. Blood O2 transport was markedly insensitive to CO2, with no Root effect and only a small Bohr effect. Red blood cell pHi was not preferentially regulated, and there was no evidence of RBC swelling or nucleoside triphosphate adjustment. Although there were no changes in arterial O2 levels during hypercapnia, ventilation immediately increased 2.7-fold through large changes in stroke volume and small changes in frequency, and declined only slightly through 24-48 h. PaCO2 equilibrated rapidly with PICO2, driving down arterial pHa, which was 65% corrected through HCO3- accumulation by 24 h. In contrast, the extradural fluid outside the brain equilibrated only very slowly, and was clearly not involved in the ventilatory stimulation. Increased ventilation during hypercapnia may be related to depression in pHa.
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PMID:Control of ventilation in the hypercapnic skate Raja ocellata: I. Blood and extradural fluid. 212 Jul 53

The purpose of this study was to investigate neonatal brain energy metabolism, acid, and lactate homeostasis in the period immediately following partial ischemia. Changes in brain buffering capacity were quantified by measuring mean intracellular brain pH, calculated from the chemical shift of Pi, in response to identical episodes of hypercarbia before and after ischemia. In addition, the relationship between brain buffer base deficit and intracellular pH was compared during and following ischemia. Thus, in vivo 31P and 1H nuclear magnetic resonance spectra were obtained from the brains of seven newborn piglets exposed to sequential episodes of hypercarbia, partial ischemia, and a second episode of hypercarbia in the postischemic recovery period. For the first episode of hypercarbia, brain buffering was similar to values reported for adult animals of other species (percentage pH regulation = 54 +/- 16%). During ischemia, the brain base deficit per unit change in pH was -19 +/- 5 mM/pH unit, which is similar to values reported for adult rats. By 20-35 min postischemia, brain acidosis partly resolved in spite of a net increase in lactate concentration. Therefore, the consumption of lactate could not explain acid homeostasis in the first 35 min following ischemia. We conclude that H+/HCO3- or other proton equivalent translocation mechanisms must be sufficiently developed in piglet brain to support acid regulation. This is surprising, because a substantial body of evidence implies these processes would be less active in immature brain. The second episode of hypercarbia, from 35 to 65 min postischemia, resulted in a smaller decrease in brain pH compared with the first episode, a result indicating an increase in brain buffering capacity (percentage pH regulation = 79 +/- 29%). This was associated with a parallel decrease in brain lactate content, and therefore acid regulation could be attributed to either continued ion translocation or the consumption of lactate. A mild decrease in brain pH and content of energy metabolites was observed, a finding suggesting that the metabolic consequences of severe postischemic hypercarbia are neither particularly dangerous or beneficial.
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PMID:Acid homeostasis following partial ischemia in neonatal brain measured in vivo by 31P and 1H nuclear magnetic resonance spectroscopy. 231 86

Erythropoietin (EPO) production in response to hypoxic hypoxia is known to be attenuated by simultaneous hypercapnia. This study aimed to investigate whether this inhibitory effect of hypercapnia is 1) a direct effect of carbon dioxide or mediated by changes in pH or bicarbonate, 2) affects also carbon monoxide hypoxia, and 3) influences either the synthesis and release of EPO or the mechanisms by which hypoxia triggers an increase in EPO production rate. We found that EPO formation in mice exposed to normobaric hypoxia (8% O2) or to carbon monoxide (0.1%) was reduced by 30 and 42% when animals were simultaneously exposed to hypercapnia (7% CO2), by 35 and 38% when subjected to metabolic acidosis (NH4Cl), and unchanged when subjected to metabolic alkalosis (NaHCO3). In animals exposed to brief hypoxia (15 min) and subsequent normoxia (2 h), metabolic acidosis did not affect EPO levels when initiated after the hypoxic period. The results indicate that acidosis inhibits hypoxia-induced triggering of EPO formation independently of PCO2 and HCO3 levels. Because this inhibitory effect is also present during carbon monoxide hypoxia, it appears not solely due to potentiated hyperpnea. Alternatively, it may result from a facilitated intrarenal oxygen release or a direct effect at the EPO production sites.
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PMID:Triggering of erythropoietin production by hypoxia is inhibited by respiratory and metabolic acidosis. 231 14

Renal acidification in renal proximal tubule is thought to be mediated by luminal Na-H antiporter and the HCO3- generated by this antiporter is removed from the cell by a basolateral Na-HCO3 cotransporter. To study the effect of respiratory acid-base disorders on these transport systems, we have measured the Na-HCO3 cotransport in basolateral membranes and Na-H antiporter in luminal membranes in control rabbits, rabbits exposed to 10% CO2 (chronic hypercapnia), and rabbits exposed to 10% O2-90% N2 (chronic hypocapnia). The Vmax of HCO3(-)-dependent 22Na uptake was significantly higher in chronic hypercapnia than controls (2.54 +/- 0.03 vs. 1.18 +/- 0.21 nmol.mg protein-1.3 s-1, P less than 0.001). Likewise, the Vmax of the Na-H antiporter was also increased compared with controls (924.9 +/- 42.1 vs. 549.1 +/- 62.8 fluorescence units (FU).300 micrograms protein-1.min-1). In chronic hypocapnia, the Vmax of Na-HCO3 cotransport was lower than controls (0.72 +/- 0.11 vs. 1.18 +/- 0.21 nmol.mg protein-1.3 s-1, P less than 0.05). There was no difference, however, in the Vmax of the Na-H antiporter between hypocapnia and control (524.2 +/- 24.3 vs. 549.1 +/- 62.8, FU.300 micrograms protein-1.min-1). The Vmaxs of the Na-HCO3 cotransport and of the Na-H antiporter in hypocapnic, control, and hypercapnic rabbits were linearly related (r = 0.81), suggesting a simultaneous adaptation of the two systems in respiratory acid-base disorders.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Na-HCO3 cotransport and Na-H antiporter in chronic respiratory acidosis and alkalosis. 256 56

Chronic hypercapnia is associated with increased proximal HCO3 reabsorption that is thought to be mediated by a Na-H antiporter. We hypothesized that chronic hypercapnia would be associated either with increased Vmax or with decreased Km of the Na-H antiporter. To test this hypothesis we made rabbits hypercapnic for 48 h by exposure to 10% CO2. In both control and hypercapnic animals, cortical luminal membranes were enriched over the homogenate 16-fold in alkaline phosphatase and 10-fold in maltase activity. The kinetic activity of the Na-H antiporter was measured by the dissipation of the quenching of acridine orange by addition of different Na concentrations. Chronic hypercapnic rabbits had significantly higher Vmax of the Na-H antiporter of luminal membranes than controls (593 +/- 81 vs. 252 +/- 40 arbitrary fluorescence units X min-1 X 300 micrograms protein-1, P less than 0.01). The Km, however, was not different between control and hypercapnic rabbits. 22Na uptake in presence of an outwardly directed pH gradient was significantly higher in vesicles from hypercapnic rabbits than controls. Amiloride inhibited the Na-H antiporter (as assessed by acridine orange quenching or 22Na uptake) to the same degree in membranes from both control and hypercapnic rabbits, suggesting that the increase in Vmax is mediated by the electroneutral component of the Na-H antiporter. In addition, under voltage clamp conditions by K and valinomycin the Vmax was still increased in membranes from hypercapnic animals, again suggesting that the increase in Vmax is mediated by the electroneutral component of the Na-H antiporter. The uptake of D-[3H]glucose by luminal membranes was not different between control and hypercapnic rabbits, indicating a specific enhancement of the Na-H antiporter. Acute hypercapnia (4 h) failed to increase the Vmax of the Na-H antiporter despite comparable increase in PCO2. Thus chronic hypercapnia, but not acute hypercapnia, induces a selective and specific increase in the Vmax of Na-H antiporter, and this may mediate the adaptation to chronic hypercapnia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Chronic hypercapnia enhances Vmax of Na-H antiporter of renal brush-border membranes. 282 Feb 41

Posthypercapnic metabolic alkalosis has been attributed to decreased HCO3 excretion because of low glomerular filtration rate (GFR), volume contraction, or chloride depletion. We have previously shown that chronic hypercapnia enhances the Vmax of the Na+-H+ antiporter. We reasoned that an increased Vmax of the Na+-H+ antiporter could play a role in the maintenance of posthypercapnic metabolic alkalosis. To test this hypothesis, we measured the kinetics of the Na+-H+ antiporter by the dissipation of the quenching of acridine orange fluorescence in purified brush-border membrane obtained from posthypercapnic rabbits. The kinetic parameters were measured in controls and in rabbits that were exposed to hypercapnia for 48 h and then allowed to breathe room air for 3, 24, or 48 h. In luminal membranes prepared from posthypercapnic animals, the Vmax of the Na+-H+ antiporter was significantly increased after 3 and 24 h but not after 48 h compared with controls. The increase in Vmax was not different from that of hypercapnic animals. There was no difference in the Km of the Na+-H+ antiporter among these five groups. Amiloride inhibited the Vmax equally in membranes from control and posthypercapnic rabbits. Proton permeability was comparable among the groups. These data indicate that the increase in Vmax in posthypercapnic rabbits is mediated through the electroneutral Na+-H+ exchange and not through conductive H+ and Na+ pathway. Glucose uptake was not different in control and posthypercapnia, indicating a selective increase in Na+-H+ antiporter activity. At 3 and 24 h posthypercapnia, HCO3 concentration was higher than control.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Na+-H+ antiporter in posthypercapnic state. 282 35

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

Bicarbonate reabsorption by the immature kidney in response to acute acid-base changes was assessed in 50 anesthetized newborn rabbits before the end of nephrogenesis. The normal newborn rabbit (age 5-12 days) is in a state of hypochloremic metabolic alkalosis (PHCO3-, 31.9 +/- 0.6 mmol/l; PCl-, 83.1 +/- 1.0) and excretes a hypertonic (Uosmol = 578 +/- 41 mosmol/kgH2O), alkaline (UpH = 7.40 +/- 0.15) urine containing 50 +/- 9 mmol/l Cl- and 13 +/- 4 mmol/l Na+. The alkalosis is probably generated by an alkaline load contained in the mother's milk and maintained by a state of chloride wasting and volume contraction. In this alkalotic model, bicarbonate reabsorption, expressed per milliliter glomerular filtration rate (GFR), correlates positively with arterial CO2 pressure (PaCO2). The ability of the immature kidney to reclaim filtered bicarbonate in response to an elevation of the plasma carbon dioxide tension remains unlimited up to PaCO2 of 110 mmHg (y = 20.7 + 0.15 x, r = 0.82, P less than 0.001). Hypercapnia is associated with a marked fall in GFR, so that the positive correlation between bicarbonate reabsorption and PaCO2 vanishes when the bicarbonate reabsorption rate is expressed in absolute terms. Bicarbonate reabsorption is strongly dependent on the filtered load during both acutely induced metabolic acidosis and alkalosis. The acid-base state of the newborn rabbit is in sharp contrast with that of most animal species, and the renal handling of bicarbonate as a function of GFR does not show signs of tubular immaturity.
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PMID:Bicarbonate reabsorption by the kidney of the newborn rabbit. 291 64


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