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

Experiments were conducted on cats under nembutal anesthesia; a study was made of pulse activity of bulbar respiratory neurons, electrical activity of the diaphragm and of the intercostal muscles; pO2, pCO2, pH, arterial blood oxygen saturation were determined in combined action of hypoxia and hypercapnia. When hypoxic gaseous mixture was given for respiration the developing hypocapnia disturbed the discharge rhythmic activity of the respiratory neurons, the respiration acquiring a pathological character of the Cheyne--Stokes type. After addition to the hypoxic gaseous mixture of 2% CO2 the gaseous composition of the arterial blood approached the initial values; this addition prevented the development of hypercapnia and disturbances of rhythmic discharge activity of the respiratory neurons. Addition of 5% CO2 to the hypoxic gaseous mixture produced a negative effect: at first it intensified and then depressed the pulse activity of the respiratory neurons, caused metabolic and respiratory acidosis, and promoted asphyxia.
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PMID:[Combined effects of hypoxia and hypercapnia on the functional state of the respiratory center]. 0 Jan 3

The combined effect upon cerebral blood flow (CBF) of an elevation of cerebrospinal fluid pressure (CSFP) and changes in respiratory CO2 was studied in nine baboons under chloralose anesthesia. The animals were mildly hyperventilated and provided with increasing amounts of CO2 in O2-air. Arterial CO2 tensions (PaCO2) increased from 17 to 58 mm Hg. Internal carotid blood flow (ICBF) was measured at normal CSFP and at hydrostatically maintained 50 mm Hg CSFP. It was found that: 1) end-tidal CO2 may be used as a substitute for arterial PaCO2 determinations; 2) this elevation of CSFP has little effect on ICBF during hypercapnia and normocapnia; however, 3) during hypocapnia the ICBF is reduced an additional 20% when CSFP is elevated; that is, ICBF is reduced 50% from normal when end-tidal CO2 is reduced to 2% at this elevated level of CSFP. Caution should be exercised during hyperventilation therapy particularly if the elevated CSFP or intracranial pressure (ICP) is not reduced to approach normal levels; in these conditions, the combination of decreasing PaCO2 and elevated ICP may reduce CBF below critical levels and thus lead to cerebral hypoxia.
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PMID:Effects of hyperventilation, CO2, and CSF pressure on internal carotid blood flow in the baboon. 0 53

Several hypotheses have been put forward to explain postdialysis hypocapnia. Three were tested in this study: impairment of tissue oxygenation by dialysis (D)-induced alkalosis (Bohr effect), the D disequilibrium syndrome, and the loss of carbon dioxide (CO2) in D fluid. In 17 patients pre-DPCO2 was significantly correlated with plasma bicarbonate concentration (HCO3) and no disproportionate reduction of PCO2 was discernible. In 10 patients using a bath acetate concentration of 38 mEq/1 PCO2 was unchanged after D (35.4 versus 35.9 mm Hg before D), and was low relative to HCO3 whic increased from 21.2 to 28.0 mEq/1. After a dialysis using an acetate concentration of 25 mEq/1 HCO3 remained constant (20.4 versus 21.1 mEq/1 pre-D), whereas PCO2 fell from 35.3 to 30.8 mm Hg (P less than 0.001). Consequently PCO2 was again low relative to HCO3. Removal of CO2 by D fluid was excluded as a cause for low blood PCO2: addition of gaseous CO2 to the bath had no influence on arterial blood gases. Since post-D hypocapnia was not prevented when HCO3 was kept constant, it was concluded that post-D alkalosis cannot be the main reason for post-D hyperventilation, and that other factors related to the process of D are responsible.
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PMID:Mechanism of post dialysis hyperventilation in patients with chronic renal insufficiency. 0 52

It is generally believed that the reduction in plasma [HCO3] characteristic of chronic hypocapnia results from renal homeostatic mechanisms designed to minimize the alkalemia produced by.the hypocapneic state. To test this hypothesis, we have induced chronic hypocapnia in dogs in which plasma [HCO3] had previously been markedly reduced (from 21 to 15 meq/liter) by the prolonged feeding of HCl. The PaCO2 of chronically acid-fed animals was reduced from 32 to 15 mm Hg by placing the animials in a large environmental chamber containing 9% oxygen. In response to this reduction in PaCO2, mean plasma [HCO3] fell by 8.6 meq/liter, reaching a new steady-state level of 6.4 meq/liter. This decrement in plasma [HCO3] is almost identical to the 8.1 meq/liter decrement previously observed in normal (nonacid-fed) animals in which the same degree of chronic hypocapnia had been induced. Thus, in both normal and HCl-fed animals, the renal response to chronic hypocapnia causes plasma [HCO3] to fall by approximately 0.5 meq/liter for each millimeter of Hg reduction in CO2 tension. By contrast, the response of plasma [H+] in the two groups was markedly different. Instead of the fall in [H+] which is seen during chronic hypocapnia in normal animals, [H+] in HCl-fed animals rose significantly from 53 to 59 neq/liter (pH 7.28-7.23). This seemingly paradoxical response is, of course, an expression of the constraints imposed by the Henderson equation and reflects the fact that the percent fall in [HCO3] in the HCl-fed animals was greater than the percent fall in PaCO2. These findings clearly indicate that in chronic hypocapnia the kidney cannot be regarded as the effector limb in a homeostatic feedback system geared to the defense of systemic acidity.
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PMID:Regulation of acid-base equilibrium in chronic hypocapnia. Evidence that the response of the kidney is not geared to the defense of extracellular (H+). 0 88

In conscious cats the ventilatory response curve to physiological range of CO2 is displaced upward by hypoxia (about 45 torr), but it rises, either parallel with, or convergent on, the normoxic curve. Thus, a positive interaction of hypoxia and hypercapnic stimuli is not observed under these circumstances. However, if during the hypoxic exposure, hypocapnia is allowed to develop, the subsequently determined CO2 ventilatory response curve will shift to the left, rise steeply, particularly in the early phase, and demonstrate a positive hypoxic hypercapnic interaction. A demonstrable interactive effect was dependent on a conditioning period of hypocapnia, and this was shown to be associated with an elevated level of lactic acid to a greater degree in cerebral venous blood than in CSF or arterial blood. The interpretation is discussed without reaching a firm conclusion of mechanism, but the results emphasize how a minor change of experimental protocol affects a basic phenomenon in the chemical control of breathing.
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PMID:The role of brief hypocapnia in the ventilatory response to CO2 with hypoxia. 1 64

Using the intra-arterial 133xenon (133Xe) method, the cerebrovascular response to acute Paco2 reduction was studied in 26 unconscious, brain-injured patients subjected to controlled ventilation. The CO2 reactivity was calculated as delta in CBF/delta Paco2. The perfusion pressure was defined as the difference between mean arterial pressure and mean intraventricular pressure. Although the CO2 reactivities did not differ significantly from that in awake, normocapnic subjects, it was low in the acute phase of injury, especially in those patients with severe outcome in whom the brain-stem reflexes were often affected. An increase of the CO2 reactivity with time was observed, indicating normal response after 1-2 weeks. Chronic hypocapnia in six unconscious patients resulted in sustained CSF pH adaptation. The question whether a delay in CSF pH adapation exerts an influence on the CO2 reactivity, and the influence of cerebral lactacidosis on the CO2 response are discussed.
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PMID:The cerebrovascular CO2 reactivity during the acute phase of brain injury. 1 91

The acid-base values of 13 patients with stable carbon dioxide tensions under controlled ventilation have been used to define the response to chronic hypocapnia in man. These patients had a respiratory paralysis and no apparent complicating disorders. Over a range of carbon dioxide tensions from 24 to 40 millimetres of mercury, the arterial blood hydrogen ion concentration decreased linearly by 0.32 nanomole per litre per millimetre of mercury decrement in carbon dioxide tension. Of primary interest was the finding that the slope of the regression line in chronic hypocapnia is close to that already reported for chronic hypercapnia. The physiological response to chronic hypocapnia in man is defined by a band that is approximately 10 nanomoles per litre (0.09 pH unit) wide for hydrogen ion concentration and 6 millimoles per litre wide for bicarbonate concentration. These significance bands may be used to differentiate additional acid-base disorders in patients with chronic hypocapnia over a clinically useful range of carbon dioxide tensions.
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PMID:Acid-base response to chronic hypocapnia in man. 2 Jan 87

After summarizing the phenomena of respiratory physiology involved in the hyperpnea test, the author studies the quantitative relation between the drop in PECO2 (pressure of CO2 in expired air) and changes in the EEG during hyperpnea. Normal subjects are divided into two groups of a hundred (6 to 19 1/2 years of age; 20 to 59 1/2 years of age). The PECO2 at rest is higher among the young subjects than among the adults, and its decline during hyperpnea is sharper. Thus, children show discrete respiratory acidosis in comparison with adults. The EEG of normal adults is practically unchanged during hyperpnea whereas, in the young group, moderate changes in the profile were observed in 45 out of 100 cases (classified empirically as normal). The PECO2 reaches a lower level in subjects showing EEG changes than in those showing none. All the reported differences are statistically significant (p less than 0.01). The probability of hyperpnea modifying the EEG profile becomes progressively less with age, and may be related to the reduced production of CO2 in older subjects. Epileptic subjects (primary generalized epilepsy) produce more CO2 than normal subjects during the hyperpnea test. The statistical data reported in the study show the importance of the size of the drop in ventilatory CO2 in the determination of EEG changes. The rest of hyperpnea in EEG can therefore be validly interpreted only if capnographic variations are measured. A standard quantitative hyperpnea test of this type should be devised, with specification of the hypocapnia level to be achieved.
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PMID:[Quantitative hyperpnea in EEG (author's transl)]. 2 61

In order to test the relationship between changes in plasma potassium concentration and pH changes of respiratory origin, we produced hypercapnia (mean PaCO2 71 mmHg = 9.5 kPa) in a group of 17 patients and hypocapnia (mean PaCO2 21 mmHg = 2.8 kPa) in another 20 patients during neurolept analgesia and intraabdominal operations. A control group of 19 patients was studied under normocapnia but otherwise identical conditions. During hypercapnia, serum potassium rose, deltaK/deltapH amounting to -0.82, -1.05 and -1.34 after 30, 60 and 90 min, respectively. During hypocapnia, serum potassium decreased, deltaK/deltapH being a little more negative than during hypercapnia (mean values -1.62, -2.44 and -1.60). Red cell potassium concentration decreased in all three groups to a similar extent. Blood lactate levels during hypercapnia decreased to 75% of control and during hypocapnia rose to a maximum of 186% of control. In order to obtain reasonable values for base excess in primarily respiratory acid-base disorders, it is necessary to use nomograms based on in vivo ECF-CO2-titration curves. With this premise, hypercapnia or hypocapnia in our patients was not associated with significant changes in base excess.
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PMID:Effects of acute hypercapnia and hypocapnia on plasma and red cell potassium, blood lactate and base excess in man during anesthesia. 3 56

In 29 cats, the extent and time-course of the pial arterial reactions to hypo- and hypercapnia were studied by means of the skull-window technique. The typical, well-known dilatations and constrictions during hyper- and hypocapnia were seen. The latent period for dilatation after the beginning of CO2-inhalation was ca. 20 sec. There was no stable relation observable between vessel diameter and arterial carbon dioxide tension (paCO2). Diameter changes lagged behind CO2-changes, indicating that CO2 acts via metabolic regulation, probably extracellular pH.
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PMID:Pial arterial reactions to hyper- and hypocapnia: a dynamic experimental study in cats. 3 9

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