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

Ventilatory responses of unanesthetized turtles to changes in the intrapulmonary CO2 content of a vascularly isolated and an intact lung were measured during spontaneous breathing. The hyperpnea associated with inhalation of CO2 by the vascularly isolated lung was 19% of that associated with inhalation of CO2 by the intact lung. Transection of the vagus nerve supplying the isolated lung abolished this response. We conclude that both inhibition of pulmonary stretch receptor discharge with increasing levels of FICO2 and a functional increase in central inspiratory volume threshold during hypercapnia contribute to tidal volume increases following CO2 inhalation in normal animals. The major component of the ventilatory response of intact turtles to increasing levels of FICO2, however, was an increase in respiratory frequency. When CO2 was inspired only by the vascularly isolated lung the increase in respiratory frequency was only 21% of that recorded when the same levels of CO2 were inspired by the intact lung. Thus the ventilatory response of turtles to increasing levels of FICO2 is primarily dependent upon concomitant hypercapnia.
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PMID:Pulmonary receptor chemosensitivity and the ventilatory response to inhaled CO2 in the turtle. 45 69

Pyrenebutyric acid (PBA), the intracellular fluorescent indicator, was used to measure the partial pressure of oxygen (PO2) in the exposed cerebral cortex of anesthetized cats at hyperbaric pressures up to 4 ATA. The validity of the PBA method for determining cortical PO2 was confirmed by demonstrating a precise linear relationship between Pao2 and the reciprocal of the fluorescence of PBA in the brain as the cat was ventilated with sequentially greater oxygen pressures while holding the Paco2 nearly constant. Increments in the Paco2 while the Pao2 was maintained at a high (about 2,000 Torr) level resulted in stepwise greater oxygen tensions in the brain until an oxygenation end point was reached with a Paco2 averaging near 122 Torr. Greater amounts of CO2 did not bring the mean PO2 of the brain, 1,017 Torr, closer to 2,000 Torr. During normocapnia the cortical PO2 was greater than the PO2 of cerebral venous blood collected from the superior sagittal sinus; however, in hypercapnia (PaCO greater than 45 Torr), the PO2 of the sinus blood exceeded the value determined in the cortex. This latter observation is taken as evidence for convective shunting of cerebral arterial blood to venous circulation when hypercapnia is present.
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PMID:Oxygen tensions measured in cat cerebral cortex under hyperbaric conditions. 45 30

The changes in the responsiveness of pial arterioles to CO2 and in the composition of cortical cerebrospinal fluid bathing these vessels were studied in the awake rabbit before and after 6 days exposure to hypercapnia (7% CO2) or hypoxia (10% O2). The vasodilator response of pial arterioles to inhalation of 3--10% CO2 was diminished after prolonged hypercapnia and enhanced after prolonged hypoxia. After both hypoxia and hypercapnia, pial arteriolar responsiveness to CO2 was immediately returned toward control levels by washing the brain surface with normal artificial cerebrospinal fluid. The bicarbonate concentration of cerebrospinal fluid bathing the pial vasculature showed a significant decrease after hypoxia and a significant increase after hypercapnia, whereas CSF pH remained unaltered. We conclude that the alteration in responsiveness of pial arterioles to CO2 is due to a change in the chemical composition of the CSF bathing these vessels, involving an adjustment in the concentration of bicarbonate ions.
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PMID:Responses of pial arterioles after prolonged hypercapnia and hypoxia in the awake rabbit. 45 36

The effects of analgesic doses of morphine on ventilation, arterial blood gas tensions, chemical control of breathing, and the ventilatory response to exercise were studied in six normal subjects. After administration of 0.2 mg/kg morphine, resting ventilation decreased primarily because of a reduction of tidal volume. Ventilatory responses to carbon dioxide and hypoxia were significantly reduced to one-half and one-third of control, respectively. Ventilatory responses at any given level of exercise were significantly reduced after morphine. However, since oxygen consumption during exercise was similarly reduced after morphine, the relationship between ventilation and metabolic rate during steady-state exercise was not altered by the drug. In addition, morphine prolonged the attainment of steady-state ventilation in four of the six subjects, similar to that reported for chemodenervated subjects. The findings suggest that blunting of chemoreception for hypoxia and hypercapnia has no effect upon the link between metabolic rate and ventilation during steady-state exercise, but the hypoxia chemoreflex may be involved in determining the dynamic characteristics of the response.
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PMID:Effects of morphine on ventilatory response to exercise. 46 50

Five anesthetized dogs were made severely hypercapnic by stepwise addition of CO2 to their inspired air. Blood PCO2 levels greater than 400 Torr were reached. During hypercapnia, the steady-state end-tidal PCO2 (PaCO2) was always higher than the simultaneous measured arterial PCO2 (PaCO2). The mean ratio PaCO2/PACO2 was 0.861 +/- 0.01. These results are consistent with the predictions of the Charged Membrane Hypothesis, that gas-to-blood PCO2 differences should be directly proportional to the blood H+ activity. The results cannot be explained by delayed equilibration of CO2 between plasma and red blood cells. The latter hypothesis predicts that, under the conditions of these experiments, the PCO2 of arterial blood should be higher than the PCO2 of end-tibal gas. The blood HCO3- during hypercapnia did not increase as much as would be predicted if the blood were exposed to CO2 in vitro. This may reflect movement of blood HCO3- generated by the buffering of carbonic acid into intracellular compartments during hypercapnia.
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PMID:Gas-to-blood PCO2 differences during severe hypercapnia. 46 74

The central control mechanism of respiratory frequency under varied alveolar carbon dioxide pressure (PACO2 20--200 Torr) was investigated in anesthetized, vagotomized, immobilized, and artificially ventilated rabbits. Central inspiratory activity indicated by phrenic motor discharge was tolerant of the extensive hypercapnia. Under light anesthesia the respiratory frequency (f) decreased in a hyperbolic fashion with increasing PACO2. Under deeper anesthesia or after mesencephalic decerebration the hyperbolic f response to PACO2 was abolished or changed to a hill-type f response (initial increase and subsequent decrease in f) and, on the average, the changes in frequency were much less. We conclude that in the absence of vagal control the respiratory frequency is primarily determined by 1) the periodicity of the bulbopontine inspiratory activity, which is little dependent on PACO2, and 2) a suprapontine acceleratory mechanism, which is depressed by increased PACO2 and highly sensitive to anesthetics. The mechanism of changes in the type of f response to CO2 is discussed.
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PMID:Phrenic activity during severe hypercapnia in vagotomized rabbits. 46 79

We have studied the propensity for periodic breathing to occur in cats anaesthetized with pentobarbitone breathing either spontaneously or with the aid of a 'servo-respirator' governed continuously by the efferent phrenic nerve activity. Sustained periodic breathing could be induced increasing 'controller gain', either by increasing the gain of the respirator, or by lung deflation, which reflexly increased controller responses to both hypoxia and hypercapnia. Periodic breathing was potentiated both by hypoxia and by diminishing the central (CO2, H+)-drive by focal cooling at the ventral surface of the medulla, two procedures which increase the relative influence of hypoxic drive. Less hypoxia was needed to produce periodic breathing at high rather than low controller gains. Reducing controller gain to zero by constant artificial respiration always abolished periodic breathing. Periodic breathing was also eradicated when the relative importance of CO2 drive was enhanced by breathing the cats with CO2-enriched gas mixtures or with 100% O2. The results are consistent with theoretical predictions for the occurrence of oscillations in the mechanisms for the chemical control of breathing and indicate that increasing controller gas can produce periodic breathing. The results further emphasize the importance of the (CO2, H+)-drive in preserving ventilatory stability.
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PMID:Experimentally induced Cheyne-Stokes breathing. 47 22

Using ten normal dogs, the right upper lobe of the lung was isolated in vivo by a balloon catheter and was artificially ventilated with nitrogen, air, 60% oxygen in nitrogen, and 60% oxygen and 20% carbon dioxide in nitrogen, while the rest of the lungs maintained a spontaneous breathing of ambient air. Aminophylline did not show a vasodilating action under severe alveolar hypoxia (PAO2: ca. 40 mmHg); on the contrary, it seemed to potentiate hypoxic pulmonary vasoconstriction. When the regional alveolar oxygen tension became less hypoxic (PAO2: ca. 70 mmHg) or higher than that in the rest of the lungs which spontaneously breathed ambient air, aminophylline showed a definite vasodilating action. Aminophylline also showed a vasodilating action in alveolar hypercapnia in the presence of alveolar hyperoxia.
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PMID:Effect of aminophylline on regional perfusion distribution in the lungs. 48 2

In chronic obstructive pulmonary disease (COPD), the neuromuscular response to an acute increase in airflow produced by external flow resistive loads (FRL) is impaired. The present study compared the response to FRL of 15 subjects with airway obstruction due to asthma and that of 15 normal subjects. FRL were applied during progressive hypercapnia and isocapnic hypoxia produced by rebreathing techniques to permit the response to be assessed at the same degree of CO2 or O2 drive. The neuromuscular response to FRL was assessed from the airway occlusion pressure developed 100 msec after the onset of inspiration (P100), as well as ventilation. During control rebreathing, ventilatory responses to hypercapnia (ratio of change in minute ventilation to change in PCO2, delta VE/delta PCO2) and hypoxia (ratio of change in VE to the change in percentage of O2 saturation, delta VE/deltaSO2) were the same in asthmatic and normal subjects despite differences in the mechanics of breathing. The P100 response to hypercapnia delta P100/delta PCO2) and hypoxia (delta P100/delta SO2) as well as absolute P100 at any given degree of O2 and CO2 drive was greater during control rebreathing in asthmatics than in normal subjects (P less than 0.05). FRL values of 9 and 18 cm H2O per L per sec applied during either hypercapnia or hypoxia increased the occlusion pressure to a greater extent in asthmatics than in normal subjects. Methacholine-induced bronchoconstriction was used to test the effect of acute airway obstruction on the response to FRL. Bronchoconstriction was associated with an increase in the P100 response to hypercapnia and to FRL, despite increases in lung volume and decreases in inspiratory muscle force. We conclude that: (1) asthmatics with airway dysfunction have an increased nonchemical drive to breathe mediated at least in part by sensory receptors in the airways; (2) asthmatics with airway obstruction respond supernormally to acute changes in resistance to airflow, unlike subjects with COPD. The failure of COPD subjects with prolonged airway obstruction to respond to FRL may be due to adaptation of the sensory mechanisms that respond to changes in airway resistance.
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PMID:The respiratory neuromuscular response to hypoxia, hypercapnia, and obstruction to airflow in asthma. 48 28

To determine the effect of inhaled carbon dioxide on acute ischemic cerebral injury, we have compared occipital visual evoked responses (VER) at baseline and during hypercapnia in 20 patients with acute unilateral cerebral infarction (ten with and ten without homonymous hemianopsia) and in ten normal controls. Visual evoked responses were judged on the basis of interhemispheral symmetry. In eight of ten controls and six of 20 patients, baseline VERs were symmetrical and remained unchanged during hypercapnia. In 14 patients with asymmetrical baseline VERs, hypercapnia caused improvement of symmetry in five, worsening in three, and no change in six. Hypercapnic vasodilation may be either beneficial or deleterious to cerebral function in patients with acute cerebral infarction.
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PMID:Hypercapnic alteration of visual evoked responses in acute cerebral infarction. 48 92

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