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

In metabolic alkalosis, a compensatory decrease in alveolar ventilation with hypercapnia has been noted only rarely. We recently managed a patient with gastric outlet obstruction from a duodenal ulcer who survived after arriving in the emergency room comatose with severe hypochloremic metabolic alkalosis, compensatory hypoventilation, and hypercapnia. We know of no report in the English literature of a patient with gastric outlet obstruction having a respiratory acidosis or hypochloremia as severe as that in our patient. Proper understanding of the pathophysiology of primary metabolic alkalosis due to gastric losses is necessary to correct the acid-base abnormalities quickly and to restore normal alveolar ventilation.
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PMID:Marked hypochloremic metabolic alkalosis with severe compensatory hypoventilation. 376 30

Intracellular pH was determined (DMO method) in European hamsters, in the spontaneously-occurring respiratory acidosis of hibernation, in hypercapnia due to breathing 12% CO2 in air in euthermy in spring, and in euthermicnormocapnic controls. From euthermy to hibernation, the temperature coefficient of pH was lowest in blood plasma and brain, intermediate in striated muscles (thigh muscles and diaphragm), and highest in heart and liver (Fig. 1). Correspondingly, the estimated dissociation ratio of the protein imidazole buffer groups, alpha Im, decreased markedly in plasma and brain, denoting an acid titration, but varied little in liver and heart. Striated muscles were intermediate (Fig. 2). Like in other mammals, intracellular responses to short-term euthermic respiratory acidosis were characterized by a partial metabolic compensation in the brain and a small metabolic acidification in striated muscles. In hibernation, a powerful metabolic compensation took place in liver and heart, nearly restoring alpha Im, but none occurred in brain (Figs. 3 to 5). The existence of an intracellular acidosis in brain and striated muscles during hibernation is in keeping with an inhibitory role of acidosis, whereas the homeostasis of intracellular alpha Im in liver and heart would subserve the eurythermal functioning of metabolic regulations in these organs, like in most organs of ectotherms.
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PMID:Intracellular pH in hibernation and respiratory acidosis in the European hamster. 383 35

Studies were conducted in anesthetized dogs to examine the influence of the renal sympathetic nerves on renal hemodynamic and renin responses during controlled hypercapnia. The dogs were subjected to unilateral denervation and tested for their responses to hypercapnia induced by inhalation of 15% CO2 in air. Simultaneous measurements of the responses from both the denervated and innervated kidneys allowed an assessment of the influence of the renal nerves on the responses during acute hypercapnia. The data indicate that reductions in renal blood flow and glomerular filtration rate and increases in renin of the renal vein during respiratory acidosis are dependent, in part, on the presence of intact renal nerves. Other factors, however, are probably also present.
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PMID:The influence of renal sympathetic nerves on renal hemodynamic and renin responses during hypercapnia in dogs. 391 20

We have recently shown that background presence of chronic metabolic acid-base disorder markedly alters in vivo acute CO2 titration curve. These studies were carried out to assess the influence of chronic respiratory acid-base disorders on response to acute hypercapnia and to explore whether the chronic level of plasma pH is the factor responsible for alterations in the CO2 titration curve. We compared whole-body responses to acute hypercapnia of dogs with preexisting chronic respiratory alkalosis (n = 8) with that of normal animals (n = 4) and animals with chronic respiratory acidosis (n = 13). Chronic respiratory alkalosis and acidosis, as well as the acute CO2 titrations, were produced in unanesthetized dogs within a large environmental chamber. For comparison with our data on chronic metabolic acidosis and alkalosis, plasma bicarbonate levels, which are secondarily altered in chronic respiratory acid-base disorders, were used as an index of chronic acid-base status of the animals. Results indicate that, as with chronic metabolic acid-base disorders, a larger increment in plasma bicarbonate occurs during acute hypercapnia when steady-state plasma bicarbonate is low (respiratory alkalosis) than when it is high (respiratory acidosis). Yet, in further analogy with the metabolic studies, plasma hydrogen ion concentration is better defended at higher plasma bicarbonate levels in accordance with mathematical relationships defined by the Henderson-Hasselbalch equation. Combined results demonstrate that the influence of chronic acid-base status on whole-body response to acute hypercapnia is independent of initial plasma pH.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Influence of chronic respiratory acid-base disorders on acute CO2 titration curve. 392 16

This article reviews normal acid-base regulation, related laboratory tests, and the potential disorders if the body's ability to compensate is disrupted. Acid derived from the oxidation of proteins and through tissue metabolism must be excreted or neutralized daily by the kidneys and lungs to maintain a proper acid-base balance. Acid-base homeostasis is normally maintained by chemical buffering, changes in renal hydrogen-ion excretion, and alterations in the rate and volume of alveolar ventilation. Metabolic disorders are characterized by disturbances in bicarbonate (HCO3-) concentration, and respiratory disorders develop with primary alterations in the partial pressure of carbon dioxide (Pco2). Metabolic acidosis is characterized by low pH, low serum HCO3- concentrations, and a compensatory decrease in Pco2 with hyperventilation. Bicarbonate administration can correct this disorder, and equations for calculating the necessary amount of HCO3- are presented. Metabolic alkalosis is characterized by a primary increase in HCO3-, compensatory hypoventilation, and an increase in Pco2 (hypercapnia). The drug therapy for this disorder is directed at either saline-responsive alkalosis or saline-resistant alkalosis. Formulas for estimating the volume requirements of patients and appropriate doses of acidifying agents are presented. Respiratory acidosis and alkalosis are also discussed. The initial therapy for the hypercapnia associated with respiratory acidosis requires reversing the underlying pulmonary disease with steroids, bronchodilators, or antibiotics. The increased Pco2 in this conditions must be lowered slowly to avoid precipitating cardiac arrhythmias and seizures. The correction of respiratory alkalosis requires elevating the Pco2 and again treating the underlying disease. Pharmacists should be knowledgeable about acid-base regulation and the disorders that frequently occur with disease because drugs are capable of inducing or exacerbating these disorders and are often key elements in therapy.
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PMID:Simple acid-base disorders. 393 55

The aim of the present study was to investigate the influence of hypoxemia combined with respiratory acidosis on the kinetics of digoxin in conscious dogs. One group of three beagles was exposed to air and 7 days later to 10% O2, 10% CO2, and 80% N2. In a second group of three dogs, the order of exposure to the two atmospheric conditions was reversed. The dogs received 25 micrograms/kg digoxin and blood and urine samples were collected over the next 29 h. At the conclusion of the second treatment, the dogs were sacrificed to determine digoxin concentrations in the left ventricle, liver, renal cortex, and skeletal muscle. Digoxin total body clearance increased from 6.2 +/- 0.9 in control to 9.0 +/- 1.0 mL X min-1 X kg-1 in hypoxemic and hypercapnic dogs (p less than 0.05). The digoxin apparent volume of distribution at steady state (Vss) was increased in the dogs with hypoxemia and hypercapnia (11.63 +/- 1.11 vs. 8.62 +/- 0.41 L/kg in the controls, p less than 0.05). As a consequence the digoxin plasma half-life remained unchanged (18.6 +/- 1.5 h in hypoxemic and hypercapnic dogs versus 20.1 +/- 2.8 h in the controls). In dogs with hypoxemia and hypercapnia, the ratio of tissue to plasma digoxin concentrations tended to increase in the liver, in the renal cortex, and in the left ventricle and remained unchanged in the left hind leg muscle. In vitro studies showed that the digoxin total binding to erythrocyte membranes was slightly increased in the dogs with hypoxemia and hypercapnia, resulting from an increase in the apparent intrinsic association constant for digoxin (p less than 0.003). It is concluded that hypoxemia combined with respiratory acidosis changes digoxin disposition in the conscious dog and is the cause of a digoxin redistribution into the tissues.
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PMID:Influence of hypoxemia and respiratory acidosis on the plasma kinetics and tissue distribution of digoxin in the conscious dog. 398 92

Previous studies from this laboratory have demonstrated that the decreased renal bicarbonate reabsorption prevailing during chronic hypocapnia is not mediated by the alkalemia that normally accompanies this acid-base disturbance but by some direct consequence of the change in PaCO2 itself. Based on the reasonable expectation that the mechanisms underlying the kidney's response to primary respiratory disturbances would be similar over the entire spectrum of physiologic carbon dioxide tensions, the present study was designed to assess whether an acidic change in systemic pH is a critical factor in the renal response to chronic hypercapnia. For this purpose, the plasma and renal responses to chronic respiratory acidosis in normal dogs were compared to those in dogs chronically fed a large hydrochloric acid (HCl) load (7 mmoles/kg/day). Exposure to 6% carbon dioxide for 7 days in a large environmental chamber induced a stable increment in PaCO2 which averaged 17 +/- 0.5 and 22 +/- 1.3 mm Hg in normal and HCl-fed animals, respectively. Steady-state plasma bicarbonate concentration rose from 22.0 +/- 0.4 to 27.1 +/- 0.5 mEq/liter in normals and from 14.7 +/- 0.7 to 24.2 +/- 0.8 mEq/liter in the HCl-fed group. As a result of these changes in PaCO2 and plasma bicarbonate, steady-state plasma hydrogen ion concentration rose in normals from 41 +/- 0.8 to 49 +/- 0.9 nEq/liter (pH 7.39 +/- 0.01 vs. 7.31 +/- 0.01) but did not change significantly in the HCl-fed group (55 +/- 1.4 vs. 56 +/- 1.4 nEq/liter; pH 7.26 +/- 0.01 vs. 7.25 +/- 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Regulation of acid-base equilibrium in chronic hypercapnia. 399 41

A recent study has shown in the conscious dog that hypoxia associated with respiratory acidosis could increase the in vivo distribution of digoxin in the myocardium. The aim of the present study was to evaluate in vitro the effects of hypoxia and (or) hypercapnic acidosis on the digoxin uptake. For this purpose, rat myocardium was incubated for 180 min with radiolabelled [3H]digoxin. The uptake of digoxin which was expressed in nanograms of digoxin bound per 100 mg of myocardium was decreased by hypoxia and increased by hypercapnic acidosis. The association of hypoxia and hypercapnic acidosis had no effect on the digoxin uptake, suggesting that in vitro hypoxia acts in an opposite way to hypercapnia.
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PMID:In vitro effects of hypoxia and (or) hypercapnic acidosis on the myocardial uptake of digoxin. 400 6

The effect of acutely induced hypoxia, hypercapnic acidosis, and the combination of the two on the amount of acetylstrophanthidin (AS) required to produce cardiac arrhythmias was determined in anesthetized dogs. Each animal was studied during ventilation with room air and again during ventilation with gas mixtures of appropriate concentrations; 24 hr separated the study periods. AS was infused intravenously at a rate of 5 mug/kg per min. Significantly less AS was required to produce arrhythmias during hypoxia and hypercapnic acidosis together than during the period with normal arterial Po(2), Pco(2), and pH (10 animals). Included in this group were two animals which had undergone previous bilateral adrenalectomy and four animals in which heart rate was maintained at the same frequency during both study periods. A significant reduction in the toxic dose of AS also was demonstrated in eight animals, two with constant heart rate, during hypoxia with normal arterial Pco(2) and pH. Hypercapnic acidosis alone (eight animals) did not significantly alter the toxic dose of AS. After the administration of propranolol (six animals) or hexamethionium (six animals), no significant difference was observed between the toxic dose of AS during hypoxia and that during ventilation with room air. Thus although hypoxia and hypercapnic acidosis together do reduce the amount of AS required to produce arrhythmias, it is the hypoxia which exerts the predominant effect on the development of this increased sensitivity to AS. Furthermore, this effect of hypoxia occurs primarily as a result of reflexly augmented sympathetic stimulation of the heart.
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PMID:Effect of acute hypoxia and hypercapnic acidosis on the development of acetylstrophanthidin-induced arrhythmias. 566 17

Studies of the arterial blood gas tensions and pH in 21 children during 24 acute attacks of asthma showed that all were hypoxic on admission to hospital, and in 10 there was evidence of carbon dioxide retention. Cyanosis, invariably present when the So(2) was below 85%, and restlessness in patients breathing air were the most reliable indices of the severity of hypoxia. There were no reliable clinical guides to the Pco(2) level. Conventional oxygen therapy in tents (25-40%) did not always relieve hypoxia, and in three cases the administration of oxygen at a concentration of 40% or over failed to produce a normal arterial oxygen tension. Uncontrolled oxygen therapy may aggravate respiratory acidosis, and three of our patients developed carbon dioxide narcosis while breathing oxygen. The necessity for blood gas measurements in the management of severe acute asthma in childhood is emphasized.
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PMID:Arterial blood gas tensions and pH in acute asthma in childhood. 566 2


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