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)

This study was designed to determine the effect of acute hyperventilation on distal nephron hydrogen ion secretion. The blood PCO2 declined and stabilized rapidly when bicarbonate loaded rats were hyperventilated. In contrast, the urine PCO2 declined slowly, resulting in an early increase in the urine minus blood (U-B) PCO2 which could not be obliterated by carbonic anhydrase infusion. Within approximately 50 min, the U-B PCO2 in the hyperventilated and carbonic anhydrase infused rats approached zero. Consequently, equilibrium between collecting duct urine and arterial blood PCO2 was then presumed to exist. This provided the basis for the subsequent studies on a series of rats. The U-B PCO2 decreased from a control of 22+/-1 mm Hg (mean+/-SEM) to 11+/-2 mm Hg (mean+/-SEM) with hypocapnia, and rose again to its control value when the blood PCO2 returned to prehyperventilation values. This decline in U-B PCO2 with acute hyperventilation could not be attributed to changes in urine flow, phosphate, or bicarbonate excretion, suggesting, therefore, a decrease in distal nephron (probably collecting duct) hydrogen ion secretion with acute hyperventilation. Possible pitfalls in the interpretation of the UB PCO2 are illustrated.
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PMID:The effect of hyperventilation on distal nephron hydrogen ion secretion. 0 92

It is well known that hypoxia, acting mainly through peripheral chemoreceptors, is an important ventilatory stimulus. It is also known that under certain circumstances hypoxia can lead to ventilatory depression, perhaps through its effect on the central nervous system. This study, utilizing dogs, was carried out to determine the degree of hypoxia required to produce ventilatory depression and to study the effects of chloralose anesthesia, variations in blood carbon dioxide tension, and peripheral chemoreceptor denervation on hypoxic ventilatory depression. In the awake, intact dog, ventilatory depression did not occur until the Pao2 = 18.6 plus or minus 0.8 mmHg (SEM). This value was not significantly different from that observed in chloralose anesthetized dogs, Pao2 = 18.7 plus or minus 0.43 mmHg. Hyper- and hypocapnia had no significant effect on the Pao2 at which ventilatory depression occurred. Denervation of either aortic or carotid chemoreceptors produced a very small change in the Pao2 of ventilatory depression, increasing it from 18.6 plus or minus 0.58 to 20.8 plus or minus 0.93 mmHg. Denervation of both aortic and carotid chemoreceptors produced a further small increase (Pao2 = 21.8 plus or minus 0.76 mm Hg). In peripheral chemoreceptor-denervated animals, hypoxia produced no significant change in ventilation until the ventilatory depression point was reached. These studies indicate that in the dog hypoxic ventilatory depression occurs only during severe hypoxia and ventilatory depression occurs only during severe hypoxia and is uninfluenced by chloralose anesthesia, hyper- or hypocapnia, and only slightly affected by chemoreceptor denervation.
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PMID:Hypoxic ventilatory depression in dogs. 111 Feb 30

Hyperammonemia increases brain glutamine levels, causes astrocytic swelling, and depresses cerebral blood flow (CBF) responsivity to CO2. Methionine sulfoximine (MSO) inhibition of glutamine synthetase activity, known to be enriched in astrocytes, prevents ammonia-induced increases in brain glutamine and water content. We tested the hypothesis that inhibition of glutamine accumulation restores CBF responsivity to CO2 during acute hyperammonemia. Pentobarbital-anesthetized rats treated with either vehicle or MSO (150 mg/kg i.p.) received a 6-hour intravenous infusion of either sodium or ammonium acetate. With subsequent induction of hypercapnia, CBF increased from 113 +/- 14 (mean +/- SEM) to 194 +/- 9 ml/min per 100 g in control rats but was unchanged from 107 +/- 13 to 79 +/- 10 ml/min per 100 g in hyperammonemic rats. Treatment with MSO in hyperammonemic rats restored the CBF response to hypercapnia (from 73 +/- 8 to 141 +/- 14 ml/min per 100 g). With induction of hypocapnia, CBF decreased from 114 +/- 11 to 88 +/- 11 ml/min per 100 g in control rats but increased from 112 +/- 13 to 142 +/- 19 ml/min per 100 g in hyperammonemic rats. Treatment with MSO in hyperammonemic rats did not fully restore the response to hypocapnia but prevented the paradoxical increase in CBF (from 80 +/- 8 to 80 +/- 8 ml/min per 100 g). In control rats, MSO did not affect CO2 responsivity. Treatment with MSO prevented ammonia-induced increases in intracranial pressure. Hyposmotic-induced increases in brain water content and intracranial pressure attenuated the CBF response to hypercapnia but, unlike hyperammonemia, did not attenuate the response to hypocapnia. In contrast to hypercapnia, vasodilation in response to arterial hypotension was intact in hyperammonemic rats. We conclude that the grossly abnormal CBF responsivity to CO2 alterations during hyperammonemia is linked to glutamine accumulation rather than ammonia per se. Cerebral edema secondary to glutamine accumulation may contribute in part to abnormal CBF responses, although other aspects of astrocyte dysfunction are likely to be important.
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PMID:Restoration of cerebrovascular CO2 responsivity by glutamine synthesis inhibition in hyperammonemic rats. 139 82

Variation of PCO2 with concomitant changes in extracellular pH (pHo) may modulate cerebrovascular resistance, but the direct actions of carbon dioxide and pHo on human cerebral arteries are unknown. In this study, we have evaluated the effects of different carbon dioxide tensions (2.7, 4.2 and 7.2 kPa) with either fixed (pHo = 7.44) or concomitant changes in pHo, on contractions induced by depolarization (potassium) or receptor stimulation (prostaglandin F2 alpha) in isolated human pial arteries. Isolated changes in PCO2 had no significant effect on either potency (unchanged EC50 value) or the maximum response (Emax) in potassium-contracted arteries. Hypercapnia with uncompensated pHo significantly decreased both EC50 and Emax values, whereas uncompensated hypocapnia significantly increased the EC50 value without any effect on Emax. Concentration-response curves induced by prostaglandin (PG) F2 alpha were shifted significantly to the right (increased EC50 = decreased potency) during both hypo- and hypercapnia, independent of changes in pHo. The maximal responses were enhanced significantly during hypocapnia (Emax = 110 (SEM 2)%), but this enhancement was converted into a slight attenuation when pHo was compensated (Emax = 92 (4)%). Hypercapnia, with or without compensation of pHo, decreased the Emax values to 69 (16)% and 73 (9)%, respectively. We conclude that hypocapnia increases contractility in human pial arteries--an effect which is reversed by compensation of pHo. In contrast, the hypercapnic decrease of PGF2 alpha-induced contractions appears to be independent of pHo. The results confirm a relationship between contractility and pHo, but do not exclude a direct action of carbon dioxide in receptor-stimulated arteries.
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PMID:Modulation by carbon dioxide and pH of the contractile responses to potassium and prostaglandin F2 alpha in isolated human pial arteries. 146 6

Alterations in arterial oxygen and carbon dioxide influence cerebrovascular resistance and therefore cerebral blood flow (CBF), but the magnitude of these CBF responses have not been well defined in normal humans. Duplex scanning (B-mode imaging and pulsed Doppler shift analysis) was used to measure internal carotid blood flow (ICBF) as an indicator of CBF in 20 normal subjects during alterations of arterial O2 and CO2. End-tidal PCO2 (PETCO2) was measured by mass spectrometry, arterial oxygen saturation by pulse oximetry, and unilateral (right) ICBF by duplex scanning. A variety of gas mixtures were administered to achieve hypoxemia (FIO2 = 0.075-0.10) and hypercapnia (FICO2 = 0.05) or the subject was asked to hyperventilate to PETCO2 = 16-24 mm Hg. The ICBF was determined five times in each of six conditions: (1) normoxia/normocapnia; (2) normoxia/hypercapnia; (3) normoxia/hypocapnia; (4) hypoxia/normocapnia; (5) hypoxia/hypercapnia; and (6) hypoxia/hypocapnia. During normoxia and normocapnia, the mean ICBF was 330 +/- 19 (SEM) mL/min. Specific CO2 reactivity was 7.4 +/- 0.7 mL/min/mmHg, which is equivalent to 2.3% +/- 0.1% of normocapnic blood flow per mm Hg change in CO2. During normocapnia, ICBF increased by 2.9 +/- 0.9 mL/min for each percentage decrease in oxygen saturation. Using an ANOVA with repeated measures to fit the responses, the following statistically significant relationship was found: ICBF (mL/min) = 333 + 6.3.(PETCO2 - 40) + 2.7 DSO2 +/- 81 where DSO2 is arterial desaturation (100 - arterial saturation). An additional "between subject" variation had a mean of 0 and a standard deviation of 82 mL/min. There was no statistically significant evidence of an interaction between O2 and CO2 response. Our data suggest that hypoxia and carbon dioxide changes will alter CBF simultaneously and additively. Duplex scanning of the internal carotid artery, which can be performed at the bedside, is sufficiently sensitive to detect changes in ICBF and internal carotid artery oxygen delivery.
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PMID:Human cerebrovascular response to oxygen and carbon dioxide as determined by internal carotid artery duplex scanning. 158 51

The effect of hypocapnia on autoregulation of cerebral blood flow (CBF) and the lower limit of autoregulation (LLA) was determined in dogs anesthetized with nitrous oxide (66%) and halothane (0.2%, end-expired concentration). CBF and cerebral vascular resistance (CVR) were determined during both normocapnia and hypocapnia (PaCO2 21-22 mmHg) at control cerebral perfusion pressure (CPP) and after reducing CPP (by hemorrhage) to 80%, 60%, 50%, and 40% of control. At control CPP hypocapnia decreased CBF from 75 +/- 5 to 48 +/- 3 ml.100 g-1.min-1 (mean +/- SEM, P less than 0.05). During both normocapnia and hypocapnia CVR decreased and CBF did not change as CPP was reduced to 60% of control. When CPP was reduced to 50% or 40% of control, CVR remained decreased and CBF fell sharply. The LLA during hypocapnia, 61 +/- 2% of control CPP, was not different than that during normocapnia, 59 +/- 3% of control CPP. Below the LLA the CBF-CPP slopes differed from zero but did not differ between hypocapnia and normocapnia. Hypocapnia does not produce a substantial shift of the LLA, and over the range of CPP values studied here, autoregulatory cerebral vasodilation only partially abolishes hypocapnia-induced cerebral vasoconstriction. The results suggest that when cerebral autoregulation is intact and in the absence of cerebrovascular disease, hypocapnia does not reduce global CBF to a level that is likely to produce ischemia and remains a useful therapeutic treatment so long as CPP remains above the LLA.
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PMID:Autoregulation of cerebral blood flow during normocapnia and hypocapnia in dogs. 249 10

Hypocarbia results in an increase in brain adenosine concentrations, presumably because of brain hypoxia associated with hypocarbic vasoconstriction. It was hypothesized that adenosine limits the degree of hypocarbic vasoconstriction. To test this hypothesis, the effects of dipyridamole and theophylline on CO2 reactivity during hypocarbia were investigated in anesthetized rats. Dipyridamole should reduce the vasoconstriction by potentiating adenosine action, whereas theophylline should increase the vasoconstriction by blocking adenosine receptors. Cortical pial arterioles of mechanically ventilated and anesthetized rats were displayed on a video monitor system through a closed cranial window. Arterial blood pressure and oxygen tension were stable. CO2 reactivity, formulated as 100 X [delta diameter (micron)/resting diameter (micron)]/delta PaCO2 (mmHg), in the hypocarbic phase was calculated before and after topical superfusion of dipyridamole (10(-6) M; n = 7) and theophylline (5 X 10(-5) M; n = 6). CO2 reactivity was significantly decreased after superfusion of dipyridamole (0.57 +/- 0.08; mean +/- SEM) as compared with mock cerebrospinal fluid (CSF) (0.97 +/- 0.17, p less than 0.05, n = 7). On the other hand, CO2 reactivity after superfusion of theophylline was increased (1.63 +/- 0.28) as compared with mock CSF (1.00 +/- 0.20, p less than 0.05, n = 6), indicating that adenosine is involved in hypocarbic vasoconstriction.
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PMID:The effects of dipyridamole and theophylline on rat pial vessels during hypocarbia. 314 92

Fourteen patients were studied during craniotomy for small supratentorial cerebral tumors. Cerebral blood flow (CBF) and cerebral metabolic rate of oxygen (CMRO2) were measured twice by a modification of the Kety-Schmidt technique using 133Xe intravenously. Anesthesia was induced with thiopental 5-7 mg X kg-1, fentanyl 0.2 mg, and pancuronium, and maintained with 0.75% inspired isoflurane concentration in 67% nitrous oxide, and moderate hypocapnia. In one group of patients (n = 7), the inspired isoflurane concentration was maintained at 0.75% throughout anesthesia. One hour after induction of anesthesia, CBF and CMRO2 averaged 31 +/- 3 ml X 100 g-1 X min-1 and 2.1 +/- 0.2 ml O2 X 100 g-1 X min-1 (X +/- SEM), respectively. During repeat studies 1 h later, CBF and CMRO2 were unchanged. In a second group of patients (n = 7), an increase in the inspired isoflurane concentration from 0.75% to 1.5% was associated with a significant decrease in CMRO2 from 2.4 +/- 0.1 to 1.9 +/- 0.1 ml O2 X 100 g-1 X min-1, and no change in CBF. It is concluded that this anesthetic regimen is safe to use in patients with small supratentorial tumors in whom only a small midline shift has occurred.
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PMID:The effect of isoflurane on cerebral blood flow and metabolism in humans during craniotomy for small supratentorial cerebral tumors. 382 91

The effects of the interaction between sympathetic nerves and prostaglandins in the cerebral circulation were examined. The hypothesis tested was that inhibition of prostaglandin synthesis by indomethacin would potentiate decreases in CBF caused by sympathetic nerve stimulation. In anesthetized rabbits, following administration of either indomethacin (10 mg/kg) or vehicle, CBF was measured with 15-micron microspheres prior to stimulation and following 3-5 min of electrical stimulation (4, 8, 16 Hz) of both superior cervical ganglia. In the vehicle group, CBF was 33-42 ml/min/100 g prior to stimulation. Bilateral sympathetic stimulation reduced blood flow to the cerebrum by 12 +/- 6% (mean +/- SEM) (p less than 0.05) at 4 Hz (n = 8), by 20 +/- 4% (p less than 0.05) at 8 Hz (n = 12), and 21 +/- 6% (p less than 0.05) at 16 Hz (n = 11). In the indomethacin group, CBF was 37-48 ml/min/100 g prior to stimulation. Bilateral stimulation decreased blood flow to the cerebrum by 7 +/- 5% (NS) at 4 Hz (n = 8), by 25 +/- 3% (p less than 0.05) at 8 Hz (n = 6), and by 20 +/- 6% (NS) at 16 Hz (n = 6). Decreases in CBF during nerve stimulation were blocked by prazosin, an alpha-adrenergic antagonist. In additional experiments, cerebral vascular constrictor responses to hypocapnia were found to be similar in the vehicle and indomethacin groups. This study provides evidence that sympathetic nerves can decrease CBF substantially even at low stimulation frequencies. Further, results of this study indicate that prostaglandins do not attenuate the effects of sympathetic stimulation on the cerebral circulation.
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PMID:Role of prostaglandins in modulating sympathetic vasoconstriction in the cerebral circulation in anesthetized rabbits. 397 19

Central apneas during sleep may arise as a result of reduction in PaCO2 below the apnea threshold. We therefore hypothesized that hyperventilation and arousals from sleep interact to cause hypocapnia and subsequent central apneas in patients with idiopathic central sleep apnea (ICSA). Accordingly, the relationships among preapneic ventilation, arousal from sleep, and the onset and duration of subsequent central apneas were examined during Stage 2 non-REM sleep in eight patients with ICSA (mean +/- SEM, 45.4 +/- 4.7 central apneas and hypopneas/h of sleep). During Stage 2 sleep, all episodes of periodic breathing with central apneas were triggered by hyperventilation. Minute ventilation (VI) was greater (6.3 +/- 0.7 versus 5.4 +/- 0.8 L/min, p < 0.05) and mean transcutaneous PCO2 (PtcCO2) was lower (37.8 +/- 1.3 versus 38.9 +/- 1.6 mm Hg, p < 0.05) during periodic breathing than during stable breathing. VI during the ventilatory phase of the periodic breathing cycle increased progressively with increasing grades of associated arousals from Grade 0 (no arousal) (10.3 +/- 1.4 L/min) to Grade 1 (EEG arousal) (12.6 +/- 1.6 L/min) to Grade 2 (movement arousal) (14.1 +/- 1.6 L/min, p < 0.01). There was a corresponding progressive increase in central apnea length following the ventilatory period from no arousal (14.1 +/- 2.0) to EEG arousal (16.4 +/- 1.8) to movement arousal (18.1 +/- 2.0 s, p < 0.01). We conclude that arousals and hyperventilation interact to trigger hypocapnia and central apneas in ICSA.
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PMID:Interaction of hyperventilation and arousal in the pathogenesis of idiopathic central sleep apnea. 804 35

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