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

The authors describe a method for Doppler ultrasound recording of flow velocity in the basilar artery of normal rabbits and rabbits with experimental subarachnoid hemorrhage (SAH). With this transcranial Doppler (TCD) model, clinical assumptions regarding flow velocity/cerebral blood flow (CBF) relationships, autoregulatory responses, and Doppler spectral waveform analysis can be tested under controlled conditions and compared with established methods of CBF measurement (hydrogen clearance). The time course of changes in flow velocity following SAH (cerebral vasospasm) is successfully demonstrated using the experimental TCD method. There are significant differences in the flow velocity and CBF responses to hypercapnia, hypocapnia, and trimethaphan-induced hypotension which indicate that TCD cannot be considered a simple alternative to CBF measurement for the study of cerebrovascular reactivity and cerebral autoregulation.
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PMID:Transcranial Doppler ultrasound studies of cerebral autoregulation and subarachnoid hemorrhage in the rabbit. 211 49

Effects of topical application of hydrogen peroxide (H2O2) on pial arteriolar diameter and cerebral prostanoid synthesis were examined in newborn pigs. H2O2 (10 mM) caused initial constriction during the 1st min, followed by prolonged (20 min) dilation that was reversed on removal of the H2O2 in piglets treated with deferoxamine. H2O2 also caused an increase in cortical periarachnoid 6-ketoprostaglandin F1 alpha, thromboxane (TX) B2, and prostaglandin (PG) E2. Indomethacin pretreatment or coadministration of SQ 29548 (PGH2/TXA2 receptor antagonist) with H2O2 blocked the constriction due to H2O2 but did not alter the dilation. The constriction, the dilation, and the increased prostanoids caused by H2O2 were not affected by topical and systemic deferoxamine (an iron chelator) or simultaneous application of FeSO4 and FeCl3. Neither prior treatment with H2O2 nor with H2O2 plus FeSO4 and FeCl3 altered pial arteriolar dilation in response to hypercapnia. Therefore the initial constriction caused by H2O2 appears to result from stimulation of prostanoid synthesis and activation of PGH2/TXA2 receptors, whereas the dilation is not caused by prostanoids. H2O2 alone does not produce detectable residual alteration of pial arteriolar responsiveness or cerebral prostanoid synthesis.
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PMID:H2O2 effects on cerebral prostanoids and pial arteriolar diameter in piglets. 233 73

The change in blood pH during hypoxia was examined using rabbits. Rabbits were divided into 4 groups according to the test gases used (O2 5.1%: CO2 5.4%: N2 89.5%, O2 4.9%: N2 95.1%, O2 2.0%: CO2 5.6%: N2 92.4% and O2 1.9%: N2 98.1%). After an intravenous injection of urethane, the rabbit was fixed on its back on an operating table and the trachea was cannulated. Animals inhaled test gases through a cylindrical unidirectional valve box connected to the cannula. Blood samples were drawn from the catheterized femoral artery. The duration of exposure was 90 min. The animals in the CO2-added 5% O2 group survived the exposure, while only 2 animals survived in the CO2-free 5% O2 group. There was a difference of about 5 mmHg in the blood PO2 between both 5% O2 groups. There was also a marked difference in the time course of changes in the hydrogen ion [( H+]) concentrations between the groups. The [H+] in the CO2-free group began to increase after an initial fall and exceeded the value of the other group, reaching acidotic levels. The acidosis (metabolic) was considered to have been caused by the accumulation of lactic acid. Under the present experimental conditions the contribution of hypoxia to this acidosis was considered to be greater than that of hypocapnia. The animals in the 2% O2 groups died by the 11 min after the start of exposure. In the CO2-free group neither hypercapnia nor acidosis was observed during the exposure. The PO2 values at apnea were about 10 mmHg in both groups.
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PMID:The effect of carbon dioxide on the changes in blood pH during hypoxia. 250 70

The intracellular energetic environment of rat hippocampal slices was manipulated by bolstering ATP levels following the addition of adenosine to the incubation medium, or by manipulating intracellular pH. Addition of 8 mM adenosine to the incubation medium increased total tissue adenylate and ATP content, but did not prolong electrical function during anoxia. Further, it resulted in long-lasting alterations in normoxic evoked responses. Intracellular pH (pHi) was changed by manipulating the bicarbonate/CO2 ratio of the incubation medium, or by adding amiloride, a hydrogen/sodium antiport blocker. Estimates of intracellular pH using the creatine kinase equilibrium agree with those obtained by Neutral red scanning spectrophotometry in control conditions. However, only Neutral red indicated an acidification with amiloride treatment, while the creatine kinase equilibrium was preferentially affected by hypercapnia, suggesting the presence of at least two pH compartments in hippocampal brain slices. These manipulations cannot be carried out easily in vivo, and provide a means of determining the importance of metabolic changes on neural function during anoxia.
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PMID:Manipulating the intracellular environment of hippocampal slices: pH and high-energy phosphates. 272 18

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

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

The most common causes of hypoxic cor pulmonale are chronic bronchitis and emphysema. Although the clinical situation in some patients is characterized early by hypoxemia, oedema is rare in patients with an arterial pO2 above 60 mm Hg. The presence of oedema can be regarded as an unfavorable prognostic indicator. For many years, peripheral oedema had been considered an expression of congestive cardiac failure; it may be assumed, however, that neither right nor left ventricular failure is prerequisite to the development of oedema. Oedema formation can be attributed to excessive retention of salt and water or a redistribution of body water into the extracellular compartment. Hypercapnia and acidosis affect direct stimulation of renal hydrogen ion secretion. The resulting electrochemical imbalance is compensated by reabsorption of sodium. Hypercapnia and, in acute phases possibly, hypoxia lead to a fall in renal blood flow mediated by alpha-adrenergic stimulation through activation of the renin-angiotensin-aldosterone system. An increase in plasma ADH may also contribute to development of oedema. The development of cor pulmonale or respiratory insufficiency can be enhanced by nocturnal hypoventilation and hypoxia during sleep as well as by sleep apnoea. Nocturnal hypoxia, smoking and reduced oxygen tension in the relevant kidney cells responsible for erythropoietin release promote the occurrence of secondary polycythaemia. For treatment of acute exacerbations in cor pulmonale associated with infections bronchitis antibiotics such as amoxycillin and cotrimoxacol are drugs of first choice. While the use of digoxin is of doubtful value, the cautious administration of diuretics may bring symptomatic relief. In addition to physiotherapy, beta-2-selective bronchodilators and nebulized bronchodilator therapy can be useful; theophyllines dilate airways and increase cardiac output but they can cause arrhythmias and a deterioration of arterial blood gases in hypoxic patients. If the patient has been treated chronically with corticosteroids, the dosage will have to be incremented; if asthma is suspected, corticosteroid treatment is essential. Controlled oxygen therapy is the most important single therapy aimed at relief of severe arterial hypoxaemia. Oxygen should be titrated initially (for the first one or two days) to achieve an arterial tension of at least 48 mm Hg. Thereafter, the oxygen flow should be increased to yield an arterial tension in excess of 60 mm Hg during continued treatment for two to three weeks.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Hypoxic cor pulmonale: a review. 294 54

This study was designed to establish the relationship between urinary pCO2 and systemic blood pCO2 during acute hypercapnia and to investigate the significance of this relationship to collecting duct hydrogen ion (H+) secretion when the urine is acid and when it is highly alkaline. In rats excreting a highly alkaline urine, an acute increase in blood pCO2 (from 42 +/- 0.8 to 87 +/- 0.8 mmHg) resulted in a significant fall in urine minus blood (U-B) pCO2 (from 31 +/- 2.0 to 16 +/- 4.2 mmHg, P less than 0.005), a finding which could be interpreted to indicate inhibition of collecting duct H+ secretion by hypercapnia. The urinary pCO2 of rats with hypercapnia, unlike that of normocapnic controls, was significantly lower than that of blood when the urine was acid (58 +/- 6.3 and 86 +/- 1.7 mmHg, P less than 0.001) and when it was alkalinized in the face of accelerated carbonic acid dehydration by infusion of carbonic anhydrase (78 +/- 2.7 and 87 +/- 1.8 mmHg, P less than 0.02). The finding of a urinary pCO2 lower than systemic blood pCO2 during hypercapnia suggested that the urine pCO2 prevailing before bicarbonate loading should be known and the blood pCO2 kept constant to evaluate collecting duct H+ secretion using the urinary pCO2 technique. In experiments performed under these conditions, sodium bicarbonate infusion resulted in an increment in urinary pCO2 (i.e., a delta pCO2) which was comparable in hypercapnic and normocapnic rats (40 +/- 7.2 and 42 +/- 4.6 mmHg, respectively) that were alkalemic (blood pH 7.53 +/- 0.02 and 7.69 +/- 0.01, respectively). The U-B pCO2, however, was again lower in hypercapnic than in normocapnic rats (15 +/- 4.0 and 39 +/- 2.5 mmHg, respectively, P less than 0.001). In hypercapnic rats in which blood pH during bicarbonate infusion was not allowed to become alkalemic (7.38 +/- 0.01), the delta pCO2 was higher than that of normocapnic rats which were alkalemic (70 +/- 5.6 and 42 +/- 4.6 mmHg, respectively, P less than 0.005) while the U-B pCO2 was about the same (39 +/- 3.7 and 39 +/- 2.5 mmHg). We further examined urine pCO2 generation by measuring the difference between the urine pCO2 of a highly alkaline urine not containing carbonic anhydrase and that of an equally alkaline urine containing this enzyme. Carbonic anhydrase infusion to hypercapnic rats that were not alkalemic resulted in a fall in urine pCO(2) (from 122+/-5.7 to 77+/-2.2 mmHg) which was greater (P <0.02) than that seen in alkalemic normocapnic controls (from 73+/- 1.9 to 43+/-1.3 mmHg) with a comparable urine bicarbonate concentration and urine nonbicarbonate buffer capacity. CO(2) generation, therefore, from collecting dust H(+) secretion and titration of bicarbonate, was higher in hypercapnic rats that in normocapnic controls. We conclude that in rats with actue hypercapnia, the U-B p(CO(2)) achieved during bicarbonate loading greatly underestimates collecting duct H(+) secretion because it is artificially influenced by systemic blood pCO(2). the deltapCO(2) is a better qualitative index of collecting duct H+ secretion that the U-B pCO(2), because it is not artificially influenced by systemic blood pCO(2) and it takes into account the urine PCO(2) prevailing before bicarbonate loading.
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PMID:Relationship of urinary and blood carbon dioxide tension during hypercapnia in the rat. Its significance in the evaluation of collecting duct hydrogen ion secretion. 298 5

The rise in urinary pCO2 above blood pCO2 which occurs in response to bicarbonate loading (i.e. the urine to blood (U-B) pCO2 gradient), is used with increasing frequency as an index of collecting duct hydrogen ion secretion. We recently proposed, however, that the U-B pCO2 gradient is not an appropriate index of collecting duct hydrogen ion secretion when blood pCO2 is altered acutely. This issue was further investigated by examining the effect of chronic hypercapnia on urinary pCO2 generation. In rats exposed to chronic hypercapnia induced by breathing 10% CO2 for 3 days in an environmental chamber, acute sodium bicarbonate infusion resulted in a U-B pCO2 lower than that of normocapnic control rats (11 +/- 4.6 and 30 +/- 1.8 mm Hg, p less than 0.001). This finding could be interpreted to indicate that collecting duct hydrogen ion secretion is depressed in rats with chronic hypercapnia. The urinary pCO2 of rats with chronic hypercapnia was lower than that of the blood (54 +/- 6.0 and 86 +/- 1.2 mm Hg, p less than 0.005, respectively). In these rats, NaHCO3 infusion, while blood pCO2 was kept constant, elicited a marked rise in urine pCO2 (from 54 +/- 6.0 to 104 +/- 6.0 mm Hg, p less than 0.005) which was not significantly different from that observed in normocapnic control rats. The infusion of carbonic anhydrase resulted in a comparable fall in urine pCO2 in hypercapnic and normocapnic rats (-27 +/- 5 and -30 +/- 3 mm Hg).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Urinary pCO2 as an index of collecting duct hydrogen ion secretion during chronic hypercapnia. 299 36

The present study evaluates the effect of acute hypercapnia on renal total CO2 (tCO2) reabsorption after inhibition of renal carbonic anhydrase. Simultaneous renal clearance studies and free-flow micropuncture studies of the superficial proximal tubule were performed on plasma-repleted Sprague-Dawley rats treated with acetazolamide, 50 mg/kg body weight. Acute hypercapnia (arterial PCO2, 120 mmHg; blood pH, 7.02) was induced by ventilation with a 10% CO2-90% O2 gas mixture. Control rats (PCO2, 49.5 mmHg, pH 7.34) were ventilated with room air. The renal fractional excretion of tCO2 was approximately 20% lower in the hypercapnic group compared with the rats given acetazolamide alone. Acute hypercapnia reduced the fractional delivery of tCO2 to the late proximal tubule by a comparable amount. The absolute proximal reabsorption of tCO2 was increased by hypercapnia to 410 +/- 47 vs. 170 +/- 74 pmol X min-1, P less than 0.05. The single nephron glomerular filtration rate was 32.6 +/- 0.7 nl X min-1 in the hypercapnic group and 43.8 +/- 1.7 nl X min-1 in the rats given acetazolamide only, P less than 0.01. Acute hypercapnia enhances renal sympathetic nerve activity. To eliminate this effect, additional experiments were performed in which the experimental kidney was denervated before study. Denervation prevented the change in the single nephron filtration rate during acute hypercapnia, but absolute and fractional proximal tCO2 reabsorption remained elevated in comparison to denervated controls. The concentration of H2CO3 in the late proximal tubule, calculated from the measured luminal pH and bicarbonate concentration and the estimated cortical PCO2, was higher in the hypercapnic group, which was a finding compatible with H2CO3 cycling from lumen into proximal tubular cell, which provided a source of hydrogen ions for secretion.
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PMID:Effect of acute hypercapnia on renal and proximal tubular total carbon dioxide reabsorption in the acetazolamide-treated rat. 308 Apr 76


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