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

Disorders of systemic acid-base balance have recently been shown to markedly alter intestinal electrolyte transport. These studies were based on earlier acid balance studies in humans and animals, data suggesting the presence of intestinal mucosal Na+-H+ and Cl-HCO-3 exchange processes and the reported effects of acid-base variables on other epithelia. In vivo studies have shown that intestinal net sodium and chloride absorption is markedly affected by systemic pH and carbon dioxide tension (Pco2). Specifically, systemic acidemia (in the rat ileum) and hypercapnia (in the rat colon) increase sodium and chloride absorption, while alkalemia and hypocapnia decrease absorption. In addition, net bicarbonate secretion (in both segments) varies directly with the plasma HCO3 concentration. The rabbit ileum has been studied both in vivo and in vitro and is affected in a similar way. The rat jejunum and rabbit distal colon and gallbladder do not respond to changes in blood pH and Pco2, consistent with the apparent absence of a mucosal Na+-H+ exchange process in these segments. Evidence suggests important roles for cellular carbonic anhydrase activity and the intracellular concentrations of hydrogen, bicarbonate, and calcium ions and calcium-calmodulin in mediating or modulating the effects of the systemic acid-base disorders. In addition, systemic pH may alter the effects of the neural and humoral mediators of intestinal transport.
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PMID:Systemic acid-base disorders and intestinal electrolyte transport. 633 Nov 93

The renal medulla can play an important role in acid excretion by modulating both hydrogen ion secretion in the medullary collecting duct and the medullary PNH3. The purpose of these experiments was to characterize the intrarenal events associated with ammonium excretion in acute acidosis. Cortical events were monitored in two ways: first, the rates of glutamine extraction and ammoniagenesis were assessed by measuring arteriovenous differences and the rate of renal blood flow; second, the biochemical response of the ammoniagenesis pathway was examined by measuring glutamate and 2-oxoglutarate, key renal cortical metabolites in this pathway. There were no significant differences noted in any of these cortical parameters between acute respiratory and metabolic acidosis. Despite a comparable twofold rise in ammonium excretion in both cases, the urine pH, PNH3, and the urine minus blood PCO2 difference (U-B PCO2) were lower during acute hypercapnia. In these experiments, the urine PCO2 was 34 mmHg (1 mmHg = 133.322 Pa) lower than that of the blood during acute respiratory acidosis while the U-B PCO2 was 5 +/- 3 mmHg in acute metabolic acidosis. Thus there were significant differences in medullary events during these two conditions. Although the urine pH is critical in determining ammonium excretion in certain circumstances, these results suggest that regional variations in the medullary PNH3 can modify this relationship.
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PMID:Importance of medullary events in ammonium excretion: studies in acute respiratory and acute metabolic acidosis. 640 34

This study examined urinary acidification shortly after recovery from chronic hypocapnia induced by hypoxemia. Distal acidification was evaluated by measuring the urinary PCO2 and urine-blood PCO2 difference (U-B PCO2) when blood PCO2 had returned to normal. In posthypocapnic rats, maximal alkalinization of the urine by acute sodium bicarbonate loading failed to increase urine PCO2 and U-B PCO2 to the level of posthypoxemic control rats and normal control rats with comparable blood pH and urine bicarbonate concentration. To test the hypothesis that decreased distal hydrogen ion secretion in posthypocapnic rats resulted from intracellular alkalosis secondary to protracted hypocarbia, posthypocapnic rats were exposed to hypercapnia of brief duration (30 min) and prolonged duration (120 min) in an attempt to restore distal acidification to normal. In posthypocapnic rats, hypercapnia of brief duration was associated with a significant increase in urine PCO2 and a fall in urine pH. Prolonged hypercapnia resulted in a marked increase in urine PCO2 and a further fall in urine pH. At any urinary bicarbonate concentration, however, the urine PCO2 and U-B PCO2 posthypocapnic rats exposed to hypercapnia were still significantly lower than in normal control rats identically subjected to prolonged hypercapnia and with comparable blood PCO2 and blood pH. Our findings indicate that distal acidification after abrupt recovery from chronic hypocapnia is decreased as if the kidneys were still under the influence of sustained hypocapnia. These findings could not be ascribed to extracellular alkalemia but could be explained by postulating that decreased urinary acidification resulted from persistence of cell alkalinity secondary to the accumulation of non-CO2 buffers generated during protracted hypocarbia. Alternatively, factors other than cell pH could mediate the adaptive decrease in distal hydrogen ion secretion of posthypocapnic rats.
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PMID:Suppression of distal urinary acidification after recovery from chronic hypocapnia. 641 9

Previous studies from this laboratory have characterized the "whole-body" response to acute hypercapnia in normal dog and humans. A more recent investigation has demonstrated that this response is markedly altered by graded degrees of chronic respiratory acidosis. The present studies were carried out to assess the influence, if any, of chronic metabolic acid-base disturbances on the acute CO2 titration curve in the dog. To this purpose we first produced a broad range of chronic plasma bicarbonate concentration of metabolic nature. Metabolic acidosis (n = 14) was produced by prolonged HCl-feeding and metabolic alkalosis (n = 11) by diuretics and a chloride-free diet. Animals with normal acid-base status (n = 4) were also studied. After the establishment of a chronic steady state of acid-base equilibrium, we then performed an acute CO2 titration of the unanesthetized dogs within a large environmental chamber. Three levels of inspired CO2 fraction (FICO2) were employed ranging from 4 to 15%. The results indicate that chronic metabolic acid-base disturbances exert a dramatic influence on the whole-body response to acute hypercapnia. The acute change in plasma bicarbonate for a given change in partial pressure of CO2 in arterial blood (PaCO2) or plasma pH decreases as a function of the chronic level of plasma bicarbonate concentration. Yet the ability of the organism to defend plasma hydrogen ion concentration is progressively strengthened as the chronic level of plasma bicarbonate increases.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Influence of chronic metabolic acid-base disorders on the acute CO2 titration curve. 641 15

In order to determine the relative roles of O2 tension and content, CO2 tension, hydrogen ion concentration, arterial blood pressure, and cardiac output in the regulation of fetal cerebral blood flow (CBF), we used radioactively labeled microspheres to measure flow to 20 major brain regions in 24 chronically catheterized fetal lambs. We continually monitored fetal heart rate and blood pressure, and periodically measured arterial PO2, PCO2, pH, and hematocrit. In addition to CBF measurements during control periods, we measured CBF during: 1) hypoxia (O2 content less than 6 ml X dl-1; O2 tension less than 15 torr) induced by having the ewe breathe a gas mixture with low O2 concentration, 2) hypercapnia (PCO2 greater than 50 torr) induced by increasing the maternal inspired CO2, 3) acidosis and alkalosis (7.60 greater than pH greater than 6.60) induced by infusing lactic acid or bicarbonate into the fetus, and 4) hypotension (blood pressure less than 35 mm Hg) and hypertension (blood pressure greater than 55 mm Hg) induced by rapidly phlebotomizing or transfusing the fetus. We used multiple regression analysis and analysis of covariance to examine the dependence of total cerebral blood flow on arterial O2 tension and content, CO2 tension, pH, blood pressure, and cardiac output.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Regional cerebral blood flow: studies in the fetal lamb during hypoxia, hypercapnia, acidosis, and hypotension. 644 Nov 42

Ventilation and cisternal cerebrospinal fluid (CSF) and arterial acid-base balance were measured in awake dogs during air control and from 1 h to 26 days of breathing 5% CO2 in air. Ventilation increased 4-fold during acute hypercapnia and then declined to a minimum at 5-10 days. Between 1-3 days and 16-26 days of hypercapnia ventilation was relatively stable at 2.5 times control. [HCO3-]CSF increased rapidly by 12 h of hypercapnia and in the steady-state [HCO3-]CSF was correlated with PCSFCO2. Between 1 h and 1.5 days of hypercapnia, increase in [HCO3-]CSF was also correlated with increase in [NH3]CSF. Despite increase in [HCO3-]CSF, there was no compensation of [H+]CSF throughout 26 days of hypercapnia. Hydrogen ion may have contributed to the control of ventilation during chronic hypercapnia since ventilation was correlated with [HCO3-]a and [HCO3-]CSF. However, a relationship between ventilation and [H+] of arterial blood and CSF during chronic hypercapnia was relatively poor or absent. Ventilatory adaptation to chronic hypercapnia could not be related to metabolism or to [NH3]CSF. The mechanism(s) by which the increase in PCO2 during chronic respiratory acidosis results in sustained elevation of ventilation remains to be resolved.
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PMID:Acid-base and ventilatory adaptation in conscious dogs during chronic hypercapnia. 652 12

We examined the relationship between cerebral blood flow (CBF) and pial vessel caliber responses to graded hemorrhagic hypotension at both normocapnia and hypercapnia in 31 anesthetized rabbits. Changes in CBF (hydrogen clearance) and pial arteriolar diameter (image splitting) were predictably related at all perfusion pressures (PP). Three autoregulatory regions were identified. 1) At PP greater than 65 mmHg, autoregulation was complete as CBF and the CBF response to hypercapnia remained at control levels. The pial vessels dilated progressively, and their response to hypercapnia increased. 2) At PP between 65 and 35 mmHg autoregulation continued but was incomplete. CBF decreased proportionately less than the corresponding reductions in PP due to continued pial vascular dilatation. Both the CBF and pial vessel responses to hypercapnia diminished. 3) At PP less than 35 mmHg, autoregulation was abolished. Pial arteriolar caliber and CBF decreased pressure passively, and there were no responses to hypercapnia. A comparison of changes in pial vascular resistance and total precapillary resistance indicated that the responses of pial vessels (particularly those less than 50 micron) paralleled the responses of the intraparenchymal arterioles.
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PMID:Pial vessel caliber and cerebral blood flow during hemorrhage and hypercapnia in the rabbit. 674 12

The hydrogen (H2) electrode technique has been applied to the measurement of local skeletal muscle blood flow (LSMBF) in experimental animals (rats, rabbits, and monkeys). LSMBF was measured during resting and postexercise states, following epinephrine injections and during CO2 inhalation. Among the limited sites studied and/or measurements obtained, significant differences in LSMBF were found in only a few instances. During hypercapnia, LSMBF was found to be increased in some muscles in rats and monkeys. The present study demonstrates that the H2 electrode technique is a simple and reliable method for measuring resting and postexercise LSMBF in anesthetized animals. This method provides measurements at discrete loci, is easily reproducible, and causes little trauma.
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PMID:Measurement of local skeletal muscle blood flow in animals by the hydrogen electrode technique. 677 45

The influence of hypercapnic acidosis upon the heart was examined in four vertebrate species. The CO2 in the tissue bath was increased from 2.7 to 15% at 12 degrees C for flounder (Platichthys flesus) and cod (Gadus morhua) and from 3 to 13% at 22 degrees C for turtle (Pseudemys scripta) and rainbow trout (Salmo gairdneri). During hypercapnia, as previously described, there was a decline and recovery of contractility in heart strips of flounder and turtle, and a sustained decrease in cod and rainbow trout. At high CO2 the increase in contractile force following increases in the extracellular Ca-concentration were smaller for the cod myocardium than for the other myocardia. The intracellular pH (pHi), measured with the DMO method, in heart strips of turtle and trout was significantly lower at high than at low CO2. This acidifying effect expressed as the increase in the intracellular concentration of hydrogen ions was larger in the turtle than in the trout myocardium. Intracellular Ca-activity, measured by efflux of 45Ca from preloaded heart strips, was unaffected by high CO2 in trout, but was raised in the other three species. Thus the ability to counteract the negative inotropic effect of hypercapnia is apparently not due to cellular buffering or extrusion of hydrogen ions. More probably it involves (a) a release of intracellular Ca; (b) a positive inotropic effect of an increase in intracellular Ca-activity.
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PMID:pHi, contractility and Ca-balance under hypercapnic acidosis in the myocardium of different vertebrate species. 680 89

Adjustments of respiration and circulation in response to alterations in the levels of oxygen, carbon dioxide and hydrogen ions in the body fluids are mediated by two distinct chemoreceptive elements, situated peripherally and centrally. The peripheral arterial chemoreceptors, located in the carotid and aortic bodies, are supplied with sensory fibres coursing in the sinus and aortic nerves, and also receive sympathetic and parasympathetic motor innervations. The carotid receptors, and some aortic receptors, are essential for the immediate ventilatory and arterial pressure increases during acute hypoxic hypoxaemia, and also make an important contribution to respiratory compensation for acute disturbances of acid-base balance. The vascular effects of peripheral chemoreceptor stimulation include coronary vasodilation and vasoconstriction in skeletal muscle and the splanchnic area. The bradycardia and peripheral vasoconstriction during carotid chemoreceptor stimulation can be lessened or reversed by effects arising from a concurrent hyperpnoea. Central chemoreceptive elements respond to changes in the hydrogen ion concentration in the interstitial fluid in the brain, and are chiefly responsible for ventilatory and circulatory adjustments during hypercapnia and chronic disturbances of acid-base balance. The proposal that the neurones responsible for central chemoreception are located superficially in the ventrolateral portion of the medulla oblongata is not universally accepted, mainly because of a lack of convincing morphological and electrophysiological evidence. Central chemosensitive structures can modify peripheral chemoreceptor responses by altering discharges in parasympathetic and sympathetic nerves supplying these receptors, and such modifications could be a factor contributing to ventilatory unresponsiveness in mild hypoxia. Conversely, peripheral chemoreceptor drive can modulate central chemosensitivity during hypercapnia.
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PMID:Role of peripheral chemoreceptors and central chemosensitivity in the regulation of respiration and circulation. 681 93


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