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)

We tested the hypothesis that altitude-induced hypocapnia in hens reduces eggshell conductance to water vapor (GH2O). Seven laying hens (Gallus domesticus) native to 1200 m were chronically exposed to high altitude (3800 m), and then to high altitude with sufficient inspired CO2 to relieve hypocapnia (3800 m + CO2). Egg GH2O was measured gravimetrically, shell thickness was measured with a micrometer, and aggregate pore area was calculated from measured values using Fick's law. Comparing results at 1200 m (n = 118) and 3800 m (n = 102), GH2O was reduced from 13.9 +/- 0.2 to 12.6 +/- 0.2 mg/(d.Torr)(mean +/- SE), shell thickness was reduced from 0.297 +/- 0.003 mm to 0.287 +/- 0.003 mm, and calculated aggregate pore area per egg was reduced from 1.97 +/- 0.03 mm2 to 1.72 +/- 0.03 mm2. When hypocapnia was relieved at 3800 m + CO2 (n = 82), GH2O was reduced even further to 11.1 +/- 0.2 mg/(d.Torr), shell thickness increased to 0.305 +/- 0.003 mm, and aggregate pore area was reduced to 1.61 +/- 0.03 mm2. Based on these results we reject our hypothesis. We conclude that hypocapnia is responsible for thin eggshells at altitude. Other physiological stimuli must cause the reductions in eggshell GH2O and pore area.
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PMID:CO2 and avian eggshell formation at high altitude. 155 44

Rings of canine bronchi were studied in vitro to determine the effects of halothane on the responses of airway smooth muscle to hypercapnia and hypocapnia. Bronchi were first contracted to 50% of maximal active force with acetylcholine (ACh), 5-hydroxytryptamine (5HT), potassium chloride (KCl), or the muscarinic agonist McN-A-343 (McN). The CO2 concentration of the bathing solution was then changed from 6% to either 1% (hypocapnia) or 10% (hypercapnia). In the absence of halothane, changes in CO2 concentration had no significant effect on muscles contracted with ACh. With all other contractile agonists, increasing the CO2 concentration caused bronchial relaxation, while decreasing the CO2 concentration caused contraction. In the presence of 2 MAC halothane, hypocapnia relaxed bronchi contracted with the muscarinic agonists ACh or McN; the responses to hypocapnia of bronchi contracted with KCl and 5HT were not significantly changed by halothane. Halothane had no effect on the responses of the bronchi to hypercapnia. We conclude that airway smooth muscle contracted with cholinergic agonist relaxes in response to hypocapnia when exposed to 2 MAC halothane; this mechanism may contribute to the depression of hypocapnic bronchoconstriction caused by halothane in vivo.
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PMID:Halothane alters the response of isolated airway smooth muscle to carbon dioxide. 156 97

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

1. In four awake dogs we measured EMG activity of three inspiratory and four expiratory muscles during sustained central chemoreceptor stimulation (CO2 inhalation), and peripheral chemoreceptor stimulation (intravenous infusion of almitrine bismesylate (almitrine)). By using this selective pharmacological stimulation of the peripheral chemoreceptors and reversibly cold-blocking pulmonary stretch receptors, we were able to determine the effects of each type of stimulation on respiratory muscle recruitment in the absence of such complicating influences as pulmonary stretch receptor feedback, cerebral hypoxia or hypocapnia, and differences in breathing pattern. 2. During 10 min of steady-state hyperpnoea (minute ventilation VI, approximately twice eupnoea) caused by either hypercapnia or isocapnic stimulation of the carotid bodies with almitrine, all three inspiratory and all four expiratory muscles demonstrated significant and sustained elevations in EMG activity. 3. With both types of chemoreceptor stimulation, as tidal volume, VT, increased, so did the mean electrical activities of the crural diaphragm (r = 0.88), costal diaphragm (r = 0.93), parasternals (r = 0.82), triangularis sterni (r = 0.74), transversus abdominis (r = 0.77), external obliques (r = 0.68) and internal intercostals (r = 0.75). 4. In each dog, the response of ventilation and of the diaphragmatic EMG to a given level of central or peripheral chemoreceptor stimulation is highly reproducible from one test day to the next. On the other hand, accessory inspiratory and expiratory abdominal and rib cage muscles in two of the four dogs showed highly significant changes from day to day in the amount of their EMG activity at any given VT. 5. During steady-state ventilatory stimulation, 2 min intervals were chosen during which the two types of chemoreceptor stimulation had caused hyperpnoeas with similar values for VT, total time per breath (TTOT) and inspiratory time divided by the total time (TI/TTOT). Comparison of EMG activities during these matched hyperpnoeas revealed that there were no differences in the activities of any of the muscles between the two forms of stimulation. We conclude that peripheral chemoreceptor stimulation causes significant and sustained recruitment of expiratory muscles even in the absence of pulmonary feedback and that both expiratory and inspiratory muscles are recruited to the same extent during peripheral chemoreceptor stimulation as they are during an identical hyperpnoea caused by central chemoreceptor stimulation.
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PMID:Respiratory muscle recruitment during selective central and peripheral chemoreceptor stimulation in awake dogs. 159 81

Previous reports suggest that isometric exercise (2-min handgrip at 50% maximal voluntary contraction [MVC]) substantially lowers intraocular pressure (IOP). The authors questioned whether the mechanism for lowered IOP in exercise is secondary to hyperventilation. Accordingly, in this study 11 subjects, with elevated IOP (greater than or equal to 18 mm Hg) and otherwise healthy, did 2 min of handgrip exercise at 50% MVC with and without carbon dioxide supplementation to maintain isocapnic conditions. Compared with a control experiment that involved neither exercise nor CO2 addition, exercise induced a fall in IOP from 18.3 to 15.6 mm Hg (P less than 0.001). This statistically significant decline in IOP persisted for 15 min after the exercise session. At the point of minimum IOP (1 min after the end of exercise), the minute ventilation was elevated from 6.5-8.1 l/min (P less than 0.05), and the end-tidal partial pressure of CO2 (PCO2) was reduced from 37.0 to 33.7 mm Hg (P less than 0.05) with respect to control values. By contrast, adding CO2 sufficient to maintain isocapnic conditions (experimental end-tidal PCO2 = 38.9 versus 38.5 mm Hg in the control study; P = not significant) abolished the exercise-induced ocular hypotension (experimental IOP = 17.8 versus 18.1 mm Hg in the control study; P = not significant). It was concluded that prevention of hypocapnia during isometric handgrip exercise blocks the subsequent fall in IOP, suggesting both that isometric exercise per se has no direct influence on IOP and that therapy for ocular hypertension could involve manipulation of blood gases.
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PMID:Isocapnia blocks exercise-induced reductions in ocular tension. 160 33

Ventilatory acclimatization (VA) to hypoxia alters cerebrovascular responses to arterial blood gas perturbations. For example, after VA, cerebral blood flow (CBF) is elevated, at a given arterial CO2 tension (PaCO2), compared to CBF before VA. This experiment examined the effects of VA to 72 h of normobaric hypoxia [arterial O2 tension (PaO2) approx. 40 mmHg, O2 saturation in arterial blood approx. 50%] on total and regional cerebrovascular resistance (CVR and rCVR) and cerebral O2 extraction fraction (OEF) in 32 conscious sheep. Four different O2-CO2 gas combinations were sequentially administered to each sheep before and after VA. CVR and rCVR were calculated from CBF (radiolabeled microspheres) and arterial and cerebral downstream pressures; OEF was calculated from arterial and cerebral venous O2 contents. After VA, during hyperoxia, CVR and rCVR tended to be lower during both hypocapnia and hypercapnia. During hypoxia, although CVR and rCVR were slightly less during hypocapnia, CVR and rCVR during hypercapnia were surprisingly increased. The post-VA increases in mean CVR and mean rCVR during hypoxic gas combinations differed from the post-VA decreases during hyperoxic gas combinations (0.04 less than or equal to P less than or equal to 0.11). In contrast, although VA decreased OEF during three of four gas combinations (P less than or equal to 0.003), there was a greater mean post-VA decrease in OEF during hypercapnic gas combinations than during hypocapnic gas combinations (P = 0.025); decreases in OEF were correlated with decreases in cerebral O2 consumption. The post-VA CVR responses may reflect altered neurocirculatory control by the arterial chemoreflex; the OEF responses suggest relative cerebral hyperperfusion.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Acclimatization to hypoxia alters cerebral convective and diffusive O2 delivery. 161 32

To evaluate the role of different vasomotor stimuli for the measurement of cerebrovascular vasomotor reactivity (VMR), 47 patients (i.e., 93 hemispheres) with various degrees of internal carotid artery (ICA) occlusive disease were studied. Patients were divided into clinical [asymptomatic, transient ischemic attack (TIA) or completed stroke] as well as angiological subgroups. Low-grade or high-grade unilateral ICA lesions were compared to bilateral ICA occlusive disease. Relative flow velocity changes within the middle cerebral artery were measured by means of transcranial Doppler during hyper- and hypocapnia (VMRTOT), during hypercapnia alone (VMRCO2), and after injection of 1 g acetazolamide (VMRACE). VMR was expressed as the percentage change in flow velocity after stimulus application as compared with flow velocity at rest. There was a close and statistically highly significant correlation of CO2-induced with acetazolamide-induced VMR (r = 0.69 in VMRTOT versus VMRACE and 0.79 in VMRCO2 versus VMRACE; P less than 0.0001; linear regression), indicating a strong similarity of the vasodilatative effects of CO2 and acetazolamide on cerebral arteries. Both stimulation techniques highly significantly differentiated between asymptomatic patients and those with TIA or completed stroke. Angiological subgroups were separated best by the acetazolamide test. Reclassification of patients into angiological subgroups by linear discriminant analysis was equally good with all three methods. We conclude that both acetazolamide- and CO2-induced stimulation of the cerebral vasomotors are valid techniques to measure reduction in perfusion reserve due to extracranial cerebrovascular occlusive disease.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Evaluation of cerebral vasomotor reactivity by various vasodilating stimuli: comparison of CO2 to acetazolamide. 172 37

We have previously shown that airway hypocapnia induced bronchoconstriction in the guinea pig lung by releasing tachykinins. To examine whether airway hypocapnia could also cause an increase in airway microvascular leakage, a tracheal segment was isolated in vivo in anesthetized guinea pigs and unidirectionally ventilated (200 ml/min) for 1 h with fully conditioned air (0% CO2) or isocapnic gas (5% CO2). The lungs were ventilated through a distally placed tracheal cannula. Microvascular leakage was quantitated by the injection of Evans blue (EB) and its extraction from the tracheal segment. EB extravasation was increased in tracheae exposed to 0% CO2 (52.3 +/- 2.0 micrograms/g wet tissue) compared with tracheae exposed to 5% CO2 (26.4 +/- 2.9 micrograms/g; p less than 0.05) and to tracheae from spontaneously breathing guinea pigs (25.2 +/- 2.3 micrograms/g; p less than 0.05). Groups of animals in which trachea were unidirectionally ventilated with 0% CO2 were then pretreated with a range of drugs in an attempt to determine the mediators responsible for the microvascular leakage with 0% CO2. Capsaicin and morphine pretreatment did not significantly alter 0% CO2-induced EB extravasation, and phosphoramidon prevented rather than increased extravasation, suggesting that tachykinins did not play a role. The hypocapnia-induced increase in microvascular leakage was, however, prevented by indomethacin pretreatment and significantly attenuated by dazmegrel, a thromboxane synthetase inhibitor. We conclude that airway hypocapnia causes microvascular leakage in the guinea pig trachea and that this effect is mediated by prostaglandins and/or thromboxane.
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PMID:Airway hypocapnia increases microvascular leakage in the guinea pig trachea. 173 4

We investigated the effects of arterial carbon dioxide tension on the myocardial tissue oxygen tensions of subepicardium and subendocardium in the anesthetized dogs. The study was done in fourteen open-chest mongrel dogs, weighing 13 +/- 1 kg, anesthetized with sodium pentobarbital (30 mg.kg-1 iv), and mechanically ventilated with 100% oxygen to maintain normocapnia. End tidal CO2 fraction (FECO2) was monitored continuously by capnograph. Regional myocardial tissue PO2 was measured using a monopolar polarographic needle electrode. Two pairs of combined needle sensors were carefully inserted, one in the epicardial and the other in the endocardial layer of the beating heart. Electromagnetic blood flow probe was applied on the left anterior descending artery (LAD). After a stable normocapnic ventilation, hypocapnia was induced by increasing the respiratory rate, and this mechanical hyperventilation was kept fixed throughout the experiments. To induce hypercapnia, exogenous carbon dioxide was added to the inspired gas step-wise until FECO2 reached 10%. Hypocapnic hyperventilation (PaCO2: 22 mmHg) invariably resulted in a significant reduction of coronary blood flow (LADBF) and left ventricular myocardial tissue PO2 in both epicardial and endocardial layers, while addition of carbon dioxide to the inspired gas (hypercapnic hyperventilation) reversed the change by increased LADBF and arterial PaCO2 in a dose-dependent manner. These results indicate that injudicious and severe hypocapnic hyperventilation may induce impaired myocardial tissue perfusion and oxygenation although normal cardiac output and arterial blood oxygenation are maintained.
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PMID:[Effect of arterial carbon dioxide tension on regional myocardial tissue oxygen tension in the dog]. 176 12

1. Ventilation has been studied during hypocapnia produced by passive mechanical ventilation in ten normal human subjects. 2. During wakefulness, disconnection of the ventilator led to inconsistent apnoea of only brief duration. During sleep, at a similar degree of hypocapnia, disconnection of the ventilator led more consistently to apnoea which was also of much longer duration; the deeper the sleep stage, the longer the apnoea. 3. The resumption of breathing during sleep could precede or follow arousal or be unaccompanied by arousal; in the absence of prior arousal, the evidence suggests that a starting end-tidal CO2 pressure (PET, CO2) less than 41 mmHg could result in an apnoea during sleep stages I and II. 4. Subjects did not report any common sensation which led them to breathe following an apnoea whilst awake. 5. Prior hyperoxia in one subject prolonged the apnoea duration in both slow-wave sleep and rapid eye movement sleep. 6. The results are interpreted as showing that even during light sleep, the maintenance of the respiratory rhythm is critically dependent on the arterial CO2 and O2 tensions. During wakefulness, other behavioural drives, which may not reach consciousness, supervene.
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PMID:The influence of induced hypocapnia and sleep on the endogenous respiratory rhythm in humans. 180 60

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