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)

Isolated rabbit hearts were perfused with rabbit red cells suspended in Ringer solution. A small volume of perfusate was recirculated for 10 min at Pco2 of 33.4 +/- 0.9 or 150.8 +/- 7.5 mmHg. Hypercapnia resulted in an increase in perfusate HCO3- concentration that was smaller than that observed when isolated perfusate was equilibrated in vitro with the same CO2 tensions (delta HCO-3e = 1.6 mM, P less than 0.01). This difference is consistent with a net movement of HCO3- into or H+ out of the mycardial cell, and cannot be accounted for by dilution of HCO3- in the myocardial interstitium. Recirculation of perfusate through the coronary circulation at normal Pco2 for two consecutive 10-min periods was not followed by changes in perfusate HCO3- concentration. A high degree of correlation (r = 0.81) was observed between intracellular HCO-3e concentration and the corresponding delta HCO-3e in individual experiments. The results suggest that transmembrane exchange of H+ or HCO3- is a buffer mechanism for CO2 in the myocardial cell.
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PMID:Myocardial CO2 buffering: role of transmembrane transport of H+ or HCO3-ions. 0 80

1. Techniques for the measurement of unidirectional flux rates in fish which require no anaesthesia or surgery are described. 2. Resting values for Cl- uptake at 10 and 17 degrees C were 8-03 +/- 1-11 and 13-52 +/- 0-95 mu-equiv. 200 g-1 h-1 (+/- S.E.), respectively; and for Na+ the rates were 15-49 +/- 0-40 and 26-30 +/- 0-36, respectively. 3. Hypercapnic acidosis caused an increase in Na+ uptake, presumably through Na+/H+ (or NH+4) exchange. It is suggested that this is a compensation mechanism leading to the increase in blood buffering observed in response to hypercapnia. 4. Alkalosis was observed following acute temperature increase and was accompanied by an increase in the rate of Cl-/HCO-3 exchange and also by an increase in Na+/H+ exchange. 5. The role of these branchial ion exchange mechanisms in overall acidbase regulation is discussed.
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PMID:Branchial ion uptake in arctic grayling: resting values and effects of acid-base disturbance. 0 14

Each of 21 dogs was bled until mean arterial blood pressure fell to 50 torr; this hemorrhagic shock state was then maintained for two hours. During hemorrhagic shock, the blood lactate concentration increased sixfold. The severe metabolic acidosis in arterial blood was partially compensated by a decreased PCO2 caused by increased ventilation. However, in mixed venous blood, the metabolic acidosis was combined with a respiratory acidosis. This hypercapnia in venous blood was indicative of the increased PCO2 in tissues poorly perfused following hemorrhage. The increase in the PCO2 of the femoral venous blood was greater than that in mixed venous blood, suggesting that some tissue beds were better perfused than those of the hind limb during shock. The intracellular lactate concentration of hind limb skeletal muscle was greatly increased in the shock state, and tissue PCO2 rose. Intracellular pH of skeletal muscle was only slightly decreased and bicarbonate concentration was unchanged during this combined metabolic and respiratory acidosis. This capacity of skeletal muscle to maintain a high HCO-3 concentration in intracellular fluid during metabolic acidosis may be an enhanced response of the mechanism responsible for maintaining (HCO-3)i normally at a level approximately ten times that which would be expected if HCO-3 were distributed passively.
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PMID:Intracellular and extracellular acid-base changes in hemorrhagic shock. 0 10

DBcAMP or crystalline glucagon was utilized to elevate the intracellular cyclic AMP concentration in isolated rat hearts. Butyric acid, a metabolite of DBcAMP, was also investigated. Their effect on the intracellular pH (pHi) as determined by the distribution of [14C]DMO was investigated. Rat hearts, perfused with a recirculated modified Krebs-Henseleit solution maintained at 30 degrees C, were exposed to respiratory acidosis by bubbling the perfusate with 20% CO2. alpha- and beta-receptor antagonists were used to block the effects of endogenous catecholamines. Hypercapnia decreased the pHi from 7.09 to 6.82. A similar degree of hypercapnia decreased the pHi to only 6.95 in the presence of DBcAMP and to only 6.96 in the presence of glucagon. The effective buffer values (delta[HCO-3]i/deltapHi) were: control, 19; butyric acid, 16; DBcAMP, 139; glucagon, 148. These data suggest that cAMP mediates the effect of norepinephrine, which has been shown to diminish the change in pHi accompanying respiratory acidosis.
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PMID:The effect of dibutyryl cyclic AMP and glucagon on the myocardial cell pH1. 2 69

The activity and the isozyme B and C levels of red cell carbonic anhydrase was examined before and during CO2 inhalation in 18 patients with chronic respiratory failure. Carbonic anhydrase B and C levels did not change during 5 min breathing of high (8-9%) and low (3-5%) CO2 mixture. Carbonic anhydrase activity decreased in patients with combined hypercarbia (Paco2 greater than or equal to 45 mmHg) and hypoxemia (Pao2 less than or equal to 60 mmHg). This was accompanied by an increase in red cell K+ content, 2, 3-DPG and Hct/Hb. The activity did not change in patients with only hypoxemia. Carbonic anhydrase activity and plasma HCO-3 concentration were positively correlated (r = 0.4, P less than 0.05). A significant inverse correlation was also found between changes in red cell K+ content and those in carbonic anhydrase activity (r = - 0.42, P less than 0.05). These results indicate that 1), there is a dissociation between activity and isozyme levels in red cell carbonic anhydrase during the initial 5 min of CO2 breathing in patients with combined hypercarbia and hypoxemia, and 2), there seems a linkage exists between K+ movement across the red cell membrane and carbonic anhydrase activity.
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PMID:Effect of CO2 on carbonic anhydrase activity and isozyme levels in respiratory failure. 41 57

Experiments were designed to determine the contribution of increased extracellular HCO3- concentration, [HCO-3e], to the net extracellular-to-intracellular HCO3- flux observed in hearts during hypercapnia. Isolated rabbit hearts were perfused by recirculating for 15-min periods a small volume of Ringer solution in which [HCO-3e] and carbon dioxide tension (PCO2) could be independently altered. A net HCO-3 flux was evidenced by a decrease in [HCO-3e] during recirculation. [HCO-3e] was randomly increased from 19 mM over a range of 19-42 mM at a constant PCO2 of 38.7 Torr. The resulting flux increased linearly with the [HCO-3e] existing at the start of recirculation. The same relationship was observed at 95.8 Torr PCO2. The disappearance of HCO-3 from the perfusate could not be explained by dilution in the interstitium or by lactate accumulation. When PCO2 was increased from 40 Torr over a range of 40-160 Torr at a constant [HCO-3e] of 20 or 30 mM, a small flux was observed only at the highest PCO2 levels. Essentially the same results were obtained when recirculation time was prolonged to 30 min. These results suggest that the major determinant of the HCO-3 flux is a change in extracellular HCO-3 concentration.
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PMID:Determinants of transmembrane bicarbonate flux during acid-base changes. 60 97

Resting level of ventilation is affected by change in extracellular fluid hydrogen ion concentration [H+] in the central nervous system (CNS) and by certain amino acid neurotransmitters within or near the medulla oblongata. Hypercapnia alters both cerebrospinal fluid (CSF) [H+] and CSF ammonia metabolized to glutamine, a precursor of the inhibitory neurotransmitter gamma-aminobutyric acid (GABA). Therefore, the effect of 1 to 2 h of hypercapnia on cerebral cortical and medullary contents of selected amino acids and bicarbonate (HCO-3) fixation rates was studied in anesthetized mongrel dogs using 11C-labeled HCO-3. Medullary taurine, glycine, alanine, and glutamate concentrations were not significantly altered by hypercapnia, but mean medullary glutamine and GABA concentrations both increased significantly (p less than 0.05), with a high correlation (r = 0.82, n = 8) between individual values. Medullary GABA and glutamine increased linearly with CSF [H+]. The rate of CNS HCO-3 fixation into CSF glutamine was negligibly small and decreased during hypercapnia, compared with the rate of medullary tissue HCO-3 fixation, which increased linearly with CSF [H+]. These observations show that there is a significant interrelationship between medullary metabolism of GABA, glutamine, bicarbonate, and CNS hydrogen ion regulation during hypercapnia.
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PMID:Relationship between central nervous system hydrogen ion regulation and amino acid metabolism in hypercapnia, II. 286 18

To study both temporal and quantitative effects of hypercapnia on the extent of pH compensation in the arterial blood, specimens of carp (Cyprinus carpio) were exposed to a PCO2 of about 7.5 mmHg (1 mmHg = 133.3 Pa) (1% CO2) in the environmental water for several weeks, and a second group of animals was subjected to an environmental PCO2 of about 37 mmHg (5% CO2) for up to 96 h. A third series of experiments was designed to test the possibility that infusion of bicarbonate would increase the extent of plasma pH compensation. Dorsal aortic plasma pH, PCO2 and [HCO3-], as well as net transfer of HCO3- -equivalent ions, NH4+, Cl- and Na+, between fish and ambient water, were monitored throughout the experiments. Exposure to environmental PCO2 of 7.5 mmHg resulted in the expected respiratory acidosis with the associated drop in plasma pH, and subsequent compensatory plasma [HCO3-] increase. The compensatory increase of plasma bicarbonate during long-term hypercapnia continued during 19 days of exposure with plasma bicarbonate finally elevated from 13.0 mmoll-1 during control conditions to 25.9 mmoll-1 in hypercapnia, an increase equivalent to 80% plasma pH compensation. Exposure to 5% hypercapnia elicited much larger acid-base effects, which were compensated to a much lesser extent. Plasma pH recovered to only about 45% of the pH depression expected at constant bicarbonate concentration. At the end of the 96-h exposure period, plasma [HCO3-] was elevated by a factor of 2.5 to about 28.2 mmoll-1. The observed increase in plasma bicarbonate concentration during 5% hypercapnic exposure was attributable to net gain of bicarbonate equivalent ions from (or release of H+-equivalent ions to) the environmental water. Quantitatively, the gain of 15.6 mmol kg-1 was considerably larger than the amount required for compensation of the extracellular space, suggesting that acid-base relevant ions were transferred for compensation of the intracellular body compartments. The uptake of bicarbonate-equivalent ions from the water was accompanied by a net release of Cl-and, to a smaller extent, by a net uptake of Na+, suggesting a 75% contribution of the Cl-/HCO-3 exchange mechanism. Infusion of bicarbonate after 48 h of exposure to 7.5 mmHg PCo2 had only a transient effect on further pH compensation. The infused bicarbonate was lost to the ambient water, and pre-infusion levels of bicarbonate were reattained within 24 h. Repetition of the infusion did not result in a notable improvement of the acid-base status.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Acid-base regulation and ion transfers in the carp (Cyprinus carpio): pH compensation during graded long- and short-term environmental hypercapnia, and the effect of bicarbonate infusion. 302 33

Carbonic anhydrase (CA) activities in gills and venous blood, acid-base balance, and haematological variables were studied during environmental hypercapnia in rainbow trout (Salmo gairdneri). Batches of 8-10 fish were exposed to about 3 or 13 mmHg Pco2 in flow-through tests of various duration from 4 h to 80 days. After initial acidosis, blood pH rose above pre-experimental values. At 3 mmHg it became normal again within 21 days, while at 13 mmHg the overshoot lasted for 80 days. In fish acclimated for 3 weeks or more to 13 mmHg Pco2, blood HCO-3 increased four to five times while plasma Cl- levels were lower and K+ higher. Na+ levels did not show any consistent trend associated with exposure to hypercapnia. After an initial acidaemia, Hct, Hb, and RBC remained relatively constant. Patterns of change in CA activity differed between gills and erythrocytes. Initially, blood CA decreased at both Pco2 levels. It then began rising after about 3 weeks and tended to reach pre-experimental values by 80 day's hypercapnia. At 13 mmHg Pco2, gill CA increased to twice the pre-experimental level. Compared with blood CA, gill CA appeared to be more specifically involved in fish acclimation to hypercapnia, which demands an increase in blood bicarbonate to provide a sufficient buffering capacity. Increased CA indicates that the gill enzyme may play a more important role than blood CA in acid-base regulation in fish during hypercapnia.
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PMID:Carbonic anhydrase activity in the blood and the gills of rainbow trout during long-term hypercapnia in hard, bicarbonate-rich freshwater. 311 52

To examine the possible contribution of active H+ secretion mediated by brush border enzymes to proximal tubule HCO-3 absorption, paired reperfusions of surface proximal convoluted tubules were performed with the inhibitor dicyclohexylcarbodiimide (DCCD). In control studies using a solution devoid of HCO-3 but containing 5.5 mM glucose, 1 mM DCCD had no effect on glucose or fluid (Na+) absorption, suggesting that this inhibitor did not interfere with sodium entry at the brush border or mitochondrial energy production (ATP synthesis). In experiments using a perfusion solution containing 18-25 mM HCO-3, DCCD caused a fall in absolute CO2 absorption of approximately 15% under eucapneic conditions and 30% during acute hypercapnia. One millimole per liter amiloride (an inhibitor of the passive Na+-H+ exchanger) caused a 15% inhibition of CO2 absorption during acute hypercapnia and a disproportionately large reduction in fluid (Na+) absorption. The latter was not due to cell poisoning, since 1 mM amiloride had no inhibitory effect on fluid or glucose absorption when a HCO-3-free perfusion solution was used. Addition of 1 mM DCCD to a perfusion solution containing either 10(-3) M amiloride or 10(-4) M acetazolamide caused a significant inhibition of CO2 absorption compared with amiloride or acetazolamide alone. The observations are consistent with the view that in addition to passive Na+-H+ exchange, active transport mediated by either a H+-ATPase or a redox-driven H+ pump in the brush border contributes significantly to HCO-3 absorption in the proximal tubule.
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PMID:Evidence for a DCCD-sensitive component of proximal bicarbonate reabsorption. 406 52

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