UMLS:C0085383 - FACTA Search

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Query: UMLS:C0085383 (hypocapnia)
1,697 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The severity of the alkalemia produced by a reduction in arterial carbon dioxide tension (PaCO2) in normal humans and animals is ameliorated by buffer and renal responses that diminish the levels of plasma bicarbonate concentration ([HCO3-]p). These adjustments have even greater potential importance in preventing extreme degrees of alkalemia when hypocapnia occurs in the presence of an initially elevated [HCO3-]p (mixed respiratory and metabolic alkalosis). The aim of the present study was to characterize the acute (approximately 3 h) and chronic (5 days) acid-base effects of respiratory alkalosis when superimposed on chronic metabolic alkalosis. Ten dogs were made alkalotic by the repeated administration of ethacrynic acid and the provision of a chloride-restricted diet. Hypocapnia (delta PaCO2 = 10 mmHg) was then superimposed by exposing the animals to 11% O2 in an environmental chamber. A large fall in [HCO3-]p occurred in the acute hypocapnic phase that was further augmented in the chronic phase; the corresponding delta [HCO3-]p/delta PaCO2 slopes were 0.43 and 0.71 meq.l-1.mmHg-1, respectively, values substantially larger than those previously reported for hypocapnia in normals as well as in animals with preexisting HCl acidosis. Hyperlactatemia was responsible, on average, for 43% of the decrement in [HCO3-]p during acute hypocapnia but for only 20% of the delta [HCO3-]p during the chronic phase of the study. The striking decrement in [HCO3-]p observed in response to the chronic reduction in PaCO2 was sufficient not only to prevent the development of extreme alkalemia but also to offset entirely the effect of hypocapnia on plasma [H+].
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PMID:Influence of acute and chronic respiratory alkalosis on preexisting chronic metabolic alkalosis. 210 57

Most phobias can be traced to aversive experiences relating to the phobic cue, but most aversive experiences do not result in phobias. Why is it that only sometimes these experiences result in classical conditioning of fear? It was hypothesized that if the subject is in a state of hypocapnia/respiratory alkalosis, classical conditioning of fear is facilitated, while extinction of fear responses is inhibited. Thirty-two healthy volunteers underwent a classical conditioning procedure with slides as conditioned stimulus, electric shocks as unconditioned stimulus, and electrodermal responding as (un) conditioned response. During conditioning, half of the subjects hyperventilated and were hypocapnic/alkalotic, while the other half was not. In both groups clear conditioning occurred, but there was no effect of hypocapnia. Results are critically discussed.
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PMID:No evidence of interference of hypocapnia/respiratory alkalosis with classical conditioning of electrodermal responses. 210 68

Nineteen patients with panic disorder received sodium D,L-lactate (racemic) and pure sodium D-lactate infusions in a pilot study. Sodium D-lactate, which is less metabolically active than L-lactate, produced panic attacks in half the patients. D-Lactate also produced hypocapnia and alkalosis, indicating hyperventilation. These findings suggest that metabolism of lactate is not necessary for the induction of panic in susceptible patients. D-Lactate appears similar to other agents that cause panic in its capacity to stimulate respiration in the preliminary study.
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PMID:Sodium D-lactate infusion of panic disorder patients. 211 19

Hyperventilation causes hypocapnia and respiratory alkalosis and thereby predisposes to coronary vasoconstriction and cardiac arrhythmia. Diagnostic methods for use between episodes have not been established. In this study of 100 patients and 25 control subjects the resting end-tidal PCO2 (Pet CO2) levels and the results of a forced hyperventilation test did not show a significant difference between the groups. However the patients hyperventilated more profoundly in response to emotional stimulation, and were less aware of inappropriate breathing and hypocapnia. It is suggested that these differences should be accommodated in cardiac rehabilitation.
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PMID:Failure of perception of hypocapnia: physiological and clinical implications. 212 16

The role of the anesthesiologist in myocardial protection is to optimize myocardial oxygen balance during the perioperative period. Nonpharmacological steps that can be taken to achieve this revolve around maintaining a satisfactory hemoglobin concentration and oxyhemoglobin saturation through maximizing ventilation. In addition, alkalosis and hypothermia should be prevented since they cause a left shift of the oxyhemoglobin dissociation curve, thus interfering with tissue oxygen delivery. Hypocarbia increases coronary vascular resistance. Blood volume must be adequate with an optimal hemoglobin concentration. Pharmacological measures should also be used, and it is important to continue through the perioperative period any previously administered cardioactive drugs. Furthermore, in the prebypass period, tachycardia may not be controlled by anesthetics; unless the tachycardia is paroxysmal, beta blockers are the drugs of choice. Depending on the cause, diastolic hypotension also needs to be treated either with volume, vasoconstrictors, or inotropes. Likewise, major hypertension can produce increased demand and, again depending on the cause, either anesthetics, vasodilators, beta blockers, or calcium blockers may be useful. Finally, myocardial ischemia without obvious cause probably should be treated with nitroglycerin or calcium blockers. During surgery, the effect of the anesthetic drugs on myocardial oxygen balance is important.
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PMID:Myocardial protection: what the anesthesiologist does. 213 51

Acid-base derangements are encountered frequently in clinical practice and many have life-threatening implications. Treatment is dependent on correctly identifying the acid-base disorder and, whenever possible, repairing the underlying causal process. Bicarbonate is the agent of choice for the treatment of acute metabolic acidosis. Controversy surrounds the use of alkali therapy in lactic acidosis and diabetic ketoacidosis, but bicarbonate should clearly be administered for severe acidosis. In most patients with mild to moderate chloride-responsive metabolic alkalosis, providing an adequate amount of a chloride salt will restore acid-base balance to normal over a matter of days. In contrast, therapy of the chloride-resistant metabolic alkalosis is best directed at the underlying disease. When alkalemia is severe, administering hydrochloric acid or a hydrochloric acid precursor may be necessary. Treatment of respiratory acidosis should be targeted at restoring ventilation; alkali should be administered only for superimposed metabolic acidosis. The therapy of respiratory alkalosis is centred on reversal of the root cause; short of this goal, there is no effective treatment of primary hypocapnia. The coexistence of more than one acid-base disorder (i.e. a mixed disorder) is not uncommon. When plasma bicarbonate concentration and arterial carbon dioxide tension (paCO2) are altered in opposite directions, extreme shifts in pH may occur. In such cases, it is imperative that the nature of the disturbance is identified early and therapy directed at both disorders.
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PMID:Rational treatment of acid-base disorders. 219 65

Conscious intact rats previously acclimated for 3 wk to barometric pressure of 370-380 Torr (3WHx) were made alkalotic for 3 h by a decrease in inspired O2 fraction from 0.10 to 0.075 at ambient barometric pressure (730-740 Torr). Controls were normoxic littermates (Nx) in which inspired O2 fraction was lowered from approximately 0.21 to 0.10 for 3 h. Arterial PCO2 decreased progressively and similarly in both groups (65-70% of control at 15 min). Initially, arterial pH increased less in 3WHx (0.09 +/- 0.004 vs. 0.15 +/- 0.008). As hypocapnia continued, delta[HCO3-]/delta pH (mmol.l-1.pH) became more negative in Nx, from -15.2 +/- 2.5 at 15 min to -37.0 +/- 2.9 at 3 h, indicating nonrespiratory compensation of alkalosis. In 3WHx, delta[HCO3-]/delta pH did not change during alkalosis. Cumulative renal excretion of base (mueq/100 g) during alkalosis increased by 73.2 +/- 11.1 in Nx and 25.4 +/- 7.3 in 3WHx. This difference was mainly due to a larger increase in HCO3- excretion in Nx. The data suggest that the smaller compensation of hypocapnic alkalosis in 3WHx is partly due to the smaller increase in renal base excretion. Because base availability limits renal base excretion, the smaller renal response of 3WHx may be secondary to the low plasma HCO3- concentration that accompanies altitude acclimation.
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PMID:Compensation of respiratory alkalosis induced after acclimation to simulated altitude. 226 57

Respiratory alkalosis is the consequence of primary hypocapnia of divergent etiologies. Any pathologic process that increases ventilation to levels beyond that required to excrete the CO2 byproduct of metabolism, will result in an inappropriately low systemic pCO2 and a tendency to an alkaline systemic pH. The increased drive to ventilation may be due predominantly to a primary increase in central nervous system activity, either within the respiratory center itself or from more centrally placed areas with neural projections that extend to and control the respiratory center. Alternatively, an increased drive to ventilation may result from an "appropriate" physiologic response to another more important stimulus that overrides the human's needs to protect pCO2 and pH. Hypoxia (of different causes), is the most important and most commonly encountered such stimulus.
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PMID:[Water-electrolyte and acid-base imbalance. IX. Respiratory alkalosis]. 227 Nov 31

The acute haemodynamic effects of intravenous infusion of adenosine, a dilator of most vascular beds, were studied in 16 patients (seven with coronary artery disease, nine with normal coronary arteries) undergoing cardiac catheterization for investigation of chest pain. At the lowest dose used (4.3 mg min-1) adenosine increased minute ventilation by 44% (P less than 0.01, n = 11) and reduced pulmonary vascular resistance by 20% (P less than 0.05) without causing other significant haemodynamic changes. Symptoms, including chest discomfort in 14 patients and dyspnoea in 11, limited the maximum dose to 8.5 +/- 2.3 mg min-1 (mean +/- SD, 108 +/- 24 micrograms kg-1 min-1). At this dose, adenosine reduced pulmonary and systemic vascular resistance (by 38% and 34%, respectively) and increased heart rate (by 34%), stroke index (by 12%) and cardiac index (by 52%). Systemic blood pressure and right atrial pressure did not change. Unexpectedly, adenosine increased left ventricular end-diastolic pressure (LVEDP) (from 5 +/- 6 to 14 +/- 10 mmHg, n = 8), pulmonary capillary wedge pressure (from 3 +/- 2 to 10 +/- 5 mmHg, n = 16) and consequently mean pulmonary artery pressure (from 10 +/- 2 to 16 +/- 5 mmHg). Minute ventilation increased by 84% (n = 11), resulting in hypocapnia (PCO2: 31 +/- 3 mmHg, n = 8) and alkalosis (pH: 7.46 +/- 0.02, n = 8). Oxygen consumption was unchanged during the infusion, but increased by 21% 5 min post infusion. All effects were similar in patients with and without coronary artery disease. Adenosine therefore causes pulmonary and systemic vasodilation and respiratory stimulation. Symptoms and an increase in LVEDP of uncertain cause, which occur with high doses, may limit the use of adenosine as a systemic vasodilator in conscious subjects. However at lower doses adenosine causes selective pulmonary vasodilation which merits further study.
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PMID:Acute haemodynamic effects of intravenous infusion of adenosine in conscious man. 228 21

A 52-year-old woman developed subjective right hemiparesthesias over a two-day period. Because of a paucity of physical findings, apparent anxiety with tachypnea, and a respiratory alkalosis with hypocapnia, a diagnosis of hyperventilation syndrome was considered. However, because of the unilateral symptoms, a computed tomography scan was performed, demonstrating a left posterior thalamic infarct. Most reports of thalamic infarct indicate altered mental status, vertical gaze palsies, or sensorimotor hemiparesis with sensory involvement predominant. The case of a patient with thalamic hemorrhage who presented with only hemiparesthesia is reported to heighten clinicians' awareness of this diagnosis.
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PMID:Thalamic hemorrhage imitating hyperventilation. 238 66

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