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

Hypoproteinemia by itself produces a metabolic alkalosis. It is not clear whether a respiratory compensation (hypercapnia) develops with this alkalosis; patients with liver cirrhosis, most of them with hypoproteinemia, are known to hyperventilate. We studied 23 clinically stable patients with hypoproteinemia, with very low albumin-to-globulin ratios (range 0.4 to 1.1), who had either liver cirrhosis (n = 12) or other medical conditions (n = 11). In both groups, there was marked hypocapnia, accompanied by alkalemia (PaCO2 values (mean +/- SD) 31 +/- 2 and 32 +/- 3 torr; pH (mean +/- SD) 7.45 +/- 0.03 and 7.47 +/- 0.03, for the patients with cirrhosis and those without, respectively). Hypoxemia was not the stimulus provoking hyperventilation. The lowering of PaCO2 was proportional to the reduction of serum albumin and total protein concentrations; no detectable difference was seen between the patients with cirrhosis and those without cirrhosis in this apparent dependence of PaCO2 on the concentration of serum proteins. Many of these clinically stable patients with hypoproteinemia, with or without liver cirrhosis, had appreciable concentrations of unidentified anions in plasma (inappropriately high anion gap). Whatever the nonrespiratory acid-base status of the patients with hypoproteinemia, their pulmonary ventilation (hypocapnia) appeared excessive when compared with subjects (presumably) without proteinemia who had similar nonrespiratory acid-base states. The mechanism responsible for the hyperventilation in hypoproteinemia and the nature of the unidentified anions in this condition are obscure.
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PMID:Hyperventilation with hypoproteinemia. 318 88

We determined regional cerebral blood flow (rCBF) using [125I]HIPDm [N,N,N'-trimethyl-N'-(2-hydroxy-3-methyl-5-iodobenzyl)-1,3-propanediamin e] and [125I]iodoantipyrine autoradiography under control and pathologic conditions (hypercapnia [acidosis], hypocapnia [alkalosis], and disrupted blood-brain barrier) conditions in 35 rats. In control rats, HIPDm rCBF (indicator fractionation method, n = 5) was lower than the corresponding IAP rCBF (diffusible indicator method, n = 4), most notably in the infratentorial regions and subcortical nuclei. In hypercapnia, rCBF increased by 100% and 37% in the HIPDm (n = 5) and IAP (n = 5) groups, respectively. In hypocapnia, IAP rCBF (n = 4) decreased 34% but HIPDm rCBF (n = 4) did not change. Following disruption of the blood-brain barrier by intracarotid infusion of mannitol in eight rats, both radiotracers (HIPDm n = 4, IAP n = 4) showed decreased rCBF to regions of disruption as defined by trypan blue extravasation. Our work indicates that modeling HIPDm uptake to quantify rCBF using the indicator fractionation method will underestimate blood flow and that HIPDm kinetics are influenced by compartmental pH dynamics that will limit the accuracy of this method in quantifying rCBF in pathologic conditions.
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PMID:Comparison of [125I]HIPDm and [125I]iodoantipyrine in quantifying regional cerebral blood flow in rats. 318 25

We evaluated to what extent acidosis and alkalosis and their respiratory and metabolic components during the first 12 hours of life occurred prior to early neonatal death and postnatal intracranial hemorrhage among 206 low birth weight, intubated premature babies participating in a clinical trial of phenobarbital prophylaxis for intracranial hemorrhage. Time-weighted indices included the time each baby spent with abnormal values of pH, PaCO2 and HCO3-. Babies whose birth weight was less than 1 kg suffered adversities associated with prolonged pH less than 7.35. Heavier birth weight babies were at increased risk of adversity if their pH fell below 7.2. Babies who were not severely acidotic initially, but became so within hours, were at prominently increased risk of death and hemorrhage. Babies who had a mild increase of PaCO2 between 45 and 60 mmHg were less likely to develop germinal matrix hemorrhage than their peers who had more severe hypercapnia. A time-weighted measure of metabolic deficit correlated with death, but not with hemorrhage. Prolonged exposure to pH greater than 7.55 was associated with reduced risk of subependymal/intraventricular hemorrhage and death, especially in babies below 1 kg birth weight. We conclude that acidosis is an antecedent of intracranial hemorrhage in low birth weight premature babies, that duration of exposure might convey important risk information, and that birth weight is a correlate of vulnerability to some pH disturbances.
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PMID:Arterial blood gas derangements associated with death and intracranial hemorrhage in premature babies. 323 3

Anesthetized spontaneously breathing rats, fitted with epicortical electrodes and catheters for sampling arterial, venous, and cerebral venous blood, were exposed to standardized progressive hypoxia. Three minutes of hypoxia sequentially caused hyperpnea, hypopnea, apnea, and cessation of electrocorticogram "spiking," of synchronization, and of background in electroencephalogram (EEG). Blood data and cerebral blood flow and metabolism were measured throughout and at "insults," i.e., at apnea and cessation events, to clarify their interdependence. Arterial and brain venous PO2 fell linearly with inspired oxygen (final value of 2% at 280 s). Hyperpnea induced arterial alkalosis; subsequent hypopnea led to near-normal PCO2 and pH when EEG ceased. Hypercapnia was more pronounced in cerebral than in systemic venous blood; time courses of pH changes were similar. Sagittal sinus blood pressure and outflow were linearly related and resembled the time course of local cerebral blood flow. Blood flow increased by 25% at apnea and only 60% at EEG silence. Cerebral metabolic rate of O2 rose during the hyperpnea phase and fell exponentially thereafter. Cerebral glucose uptake and lactate release increased within the first 3 min but fell abruptly when cortico-electric spiking ceased. Time courses of cerebral O2 consumption and spike rate were linearly related; both showed inverse linear relations to cerebral perfusion. The hypoxic insults were well defined by blood data; critical PO2 values were lower than previously assumed. This model is proving to be a useful, controlled method by which mechanisms of cerebral hypoxia tolerance may be studied in vivo.
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PMID:Progressive hypoxia until brain electrical silence: a useful model for studying protective interventions. 324 75

The relationships between pHi (intracellular pH) and phosphate compounds were evaluated by nuclear magnetic resonance (NMR) in normo-, hypo-, and hypercapnia, obtained by changing fractional inspired concentration of CO2 in dogs anesthetized with 0.75% isoflurane and 66% N2O. Phosphocreatine (PCr) fell by 2.02 mM and Pi (inorganic phosphate) rose by 1.92 mM due to pHi shift from 7.10 to 6.83 during hypercapnia. The stoichiometric coefficient was 1.05 (r2 = 0.78) on log PCr/Cr against pHi, showing minimum change of ADP/ATP and equilibrium of creatine kinase in the pH range of 6.7 to 7.25. [ADP] varied from 21.6 +/- 4.1 microM in control (pHi = 7.10) to 26.8 +/- 6.3 microM in hypercapnia (pHi = 6.83) and 24.0 +/- 6.8 microM in hypocapnia (pHi = 7.17). ATP/ADP X Pi decreased from 66.4 +/- 17.1 mM-1 during normocapnia to 25.8 +/- 6.3 mM-1 in hypercapnia. The ADP values are near the in vitro Km; thus ADP is the main controller. The velocity of oxidative metabolism (V) in relation to its maximum (Vmax) as calculated by a steady-state Michaelis-Menten formulation is approximately 50% in normocapnia. In acidosis (pH 6.7) and alkalosis (pH 7.25), V/Vmax is 10% higher than the normocapnic brain. This increase of V/Vmax is required to maintain cellular homeostasis of energy metabolism in the face of either inhibition at extremes of pH or higher ATPase activity.
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PMID:Relationship between intracellular pH and energy metabolism in dog brain as measured by 31P-NMR. 359 78

Studies of acutely induced hyperammonemia and chronic hyperammonemia associated with liver dysfunction suggest that cerebral blood flow (CBF) and O2 consumption (CMRO2) become uncoupled and that CMRo2 may depend on arterial CO2 tension (PaCO2). We examined CBF (radiolabeled microspheres) and CMRO2 during hypercapnia (PaCO2 congruent to 74 Torr) and hypocapnia (PaCO2 congruent to 21 Torr) both before and during intravenous ammonium acetate infusion in pentobarbital-anesthetized dogs. Continuous infusion over 120 min produced stable increases of arterial ammonia levels (1,400 mumol/l) by 30 min, whereas CBF, CMRO2, and O2 extraction (measured at sagittal sinus) remained unchanged when PaCO2 was held constant (congruent to 35 Torr). Acute hyperammonemia attenuated the increase in CBF during hypercapnia by 44% and abolished the decrease in CBF during hypercapnia. Regional blood flow to pons and midbrain increased under normocapnic conditions, and midbrain blood flow increased further during hypocapnia. Sodium acetate infusion did not affect CBF responses to CO2. Thus we failed to observe an uncoupling of global CBF and CMRO2 during normocapnic hyperammonemia, or an interaction of CO2 and ammonia on CMRO2, although the increased pons and midbrain blood flow may reflect regional effects of ammonia on reticular activating system metabolism. On the basis of the literature, we suggest that the attenuated hypercapnic CBF response may arise from impaired glial regulation of extracellular potassium and bicarbonate concentrations and that lactic acid production, enhanced by combined alkalosis and hyperammonemia, may contribute to the abolition of hypocapnic vasoconstriction.
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PMID:Interaction of CO2 and ammonia on cerebral blood flow and O2 consumption in dogs. 392 Sep 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 American Heart Association's current standards for CPR indicate that acid-base therapy should be guided by measurements of arterial blood gases. However, we have discovered a striking discrepancy between arterial and venous blood gases during CPR: severe venous hypercarbia and acidosis may coexist with simultaneous arterial alkalosis. Arterial blood gases during CPR, therefore, may not accurately reflect the acid-base status of mixed venous blood and thus may fail to indicate systemic acid-base status.
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PMID:Arterial blood gases fail to reflect acid-base status during cardiopulmonary resuscitation: a preliminary report. 405 33

In anaesthetized dogs, a mixed acid-base disturbance was induced by adding a pronounced metabolic alkaline to an established respiratory acidosis or alkalosis. Cerebral blood flow (CBF) was measured by the radioisotope washout method. In the hypocapnic dogs, the addition of metabolic alkalosis did not significantly change cerebral blood flow. In the hypercapnic dogs, the intravenous infusion of alkali led to a substantial reduction of cerebral blood flow, parallelled by a reduction of cerebrovenous oxygen tension. Acid-base analysis of cerebrospinal fluid (CSF) indicated an increased bicarbonate concentration. Hypercapnia is suggested to facilitate the passage of bicarbonate over the blood-brain barrier, leading to cerebral vasoconstriction by means of increased extravascular pH.
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PMID:Influence on cerebral blood flow of infusion of sodium bicarbonate during respiratory acidosis and alkalosis in the dog. 627 52

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