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Query: UMLS:C0020440 (
hypercapnia
)
7,939
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Recent investigations have shown that the calcium channel blocker verapamil attenuated the hypoxic ventilatory chemosensitivity of carotid body in animals. To determine whether this is also the case in humans, transient physiological chemodenervation by O2 breaths (withdrawal test) during sustained hypoxia (N = 7), and ventilatory and circulatory responses to progressive hypoxia and
hypercapnia
(N = 8) were examined after oral administration of verapamil. During sustained hypoxia after verpamil, there was a significant reduction of withdrawal response from 5th to 25th min value (p < 0.01), but not after placebo. On the other hand, no significant difference in ventilatory responses to progressive hypoxia and
hypercapnia
was observed after verapamil.
Verapamil
run reveals similar features with placebo run in circulatory parameters except blood pressure response, which tended to be suppressed by verapamil. We conclude that verapamil attenuates peripheral chemoreceptor activity with time during sustained mild hypoxia in normal adult humans and this may be explained by delayed depletion in intracellular Ca2+ for chemotransduction of the peripheral chemoreceptors.
...
PMID:Effect of verapamil on ventilatory and circulatory responses to hypoxia and hypercapnia in normal subjects. 149 1
1. The effects of hypoxaemia, hyperoxaemia, alkalosis, acidosis, hypocarbia with alkalosis or
hypercarbia
with acidosis on the blood pressure and pulse rate responses to verapamil were studied in chloralose-anaesthetized rats. 2. At a fixed stroke volume (10 mL/kg) and rate (80 strokes/min; except for the hypocarbic group at 160 strokes/min), hypoxaemia, hyperoxaemia,
hypercarbia
with acidosis, or hypocarbia with alkalosis was induced by artificial ventilation with gas mixtures containing 17% O2, 28% O2, 23% O2, with 5% CO2, or 17% O2, without CO2 respectively. Acidosis or alkalosis was produced by intravenous infusion of 1 mol/L HCl or 1 mol/L NaHCO3 respectively, in animals artificially ventilated with room air. 3. Changes in individual blood gas/pH parameters had no significant effect on blood pressure except for acidosis which caused a significant decrease. Effects on pulse rate were significant increases in the alkalosis and
hypercarbia
groups, decrease in the acidosis group, while in other conditions no significant changes were recorded. 4. In the controls, intravenous injections of verapamil 20-320 micrograms/kg caused dose-dependent increases in mean blood pressure, while effects on pulse rate were not marked. 5. The hypotensive responses to verapamil were significantly alleviated or enhanced in the presence of alkalosis or acidosis respectively.
Verapamil
also caused greater falls in pulse rate during acidosis. Effects of Po2 changes were not statistically significant. The influence of PCO2 changes remained unclear. 6. The present findings suggest that changes in blood pH may play a more important role than Po2 alterations in affecting the cardiovascular responses to verapamil in the presence of blood gas abnormalities.
...
PMID:Effects of blood gas/pH abnormalities on the cardiovascular actions of verapamil in rats. 212 29
The effects of subcutaneous doses of morphine and verapamil on respiratory and cardiovascular parameters have been assessed in conscious rats.
Verapamil
(10 mg kg-1) was injected simultaneously with morphine (16 mg kg-1) or at 10, 30, or 60 min before morphine administration. Morphine induced respiratory depression, as indicated by marked
hypercapnia
, hypoxia and acidosis, and caused marked tachycardia. Although morphine produced only a minor and inconsistent (but statistically significant, P less than 0.01) reduction of mean arterial blood pressure, morphine potentiated verapamil-induced hypotension.
Verapamil
suppressed morphine-induced
hypercapnia
only when injected simultaneously with morphine.
Verapamil
alone did not affect arterial blood gases or pH, but decreased heart rate and mean arterial blood pressure.
Verapamil
attenuated and delayed the maximum positive chronotropic effects of morphine at all times tested. Antagonism by verapamil of respiratory depression and tachycardia produced by morphine was unrelated to morphine levels in plasma. Thus, the explanation of verapamil-morphine interactions on respiration and cardiovascular function is not pharmacokinetic.
...
PMID:Time course of verapamil interaction with morphine effects on physiological parameters in rats. 257 6
Variations of arterial PCO2 and pH are known to influence myocardial blood flow (MBF) in that
hypercapnia
results in a coronary vasodilatation, while hypocapnia possibly decreases MBF. The present study was performed to examine if hypocapnia and
hypercapnia
might influence the sensitivity to exogenous administration of adenosine. Aminophylline, an adenosine receptor blocking agent, was administered to rule out the effect of endogenously liberated adenosine during variations of PCO2 and pH. In the last part of the study, it was examined whether verapamil, a calcium-channel blocker, might influence the MBF response to variations in PCO2 and pH. Closed-chest dogs were anaesthetized with pentobarbital, and hypocapnia induced by hyperventilation. Carbon dioxide was added to the inspiratory gas to create normocapnia and
hypercapnia
. In the control group hypocapnia did not significantly reduce MBF although a decrease in coronary sinus (CS) SO2 indicated a coronary vasoconstriction. During continuous adenosine infusion (7.5 +/- 0.3 mg/kg/h) which increased MBF 116% during normocapnia, creating hypocapnia caused a 40% decrease in MBF.
Hypercapnia
seemed to potentiate the vasodilating effect of adenosine. During administration of aminophylline hypocapnia did not cause any decrease in MBF, while
hypercapnia
increased MBF by 39%, and these results are in harmony with the results obtained in the control group without aminophylline.
Verapamil
did not result in any altered MBF response to hypocapnia and
hypercapnia
when compared to the unblocked control group. These observations do not support the idea of any major influence of the Ca2+ fluxes blocked by verapamil as the cause of MBF changes during variations in PCO2 and pH.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Adenosine modifies canine myocardial blood flow response to hypocapnia and hypercapnia, while aminophylline and verapamil do not. 312 Mar 3
Nimodipine, a dihydropyridine that interacts with a Ca++ channel-associated binding site, when delivered (30 to 150 micrograms/kg) intra-arterially (ia) to enflurane-anesthetized cats, produced a dose-dependent suppression of seizures evoked by pentylenetetrazol. A comparable suppression was produced by clonazepam (1 to 30 micrograms/kg, ia). Phenytoin was maximally effective only at nearly lethal doses (90 mg/kg, ia).
Verapamil
, a diphenylalkylamine that interacts with a separate Ca++ channel-associated site, at the maximum nonlethal dose (6 mg/kg, ia) resulted in a mild facilitation of seizure activity. The drug vehicle used in these studies (50% polyethylene glycol-400) had no effect when given alone. Regional cerebral blood flow (rCBF) as measured by the clearance of xenon-133 was markedly elevated immediately after the onset of seizure activity (89 +/- 3 to 168 +/- 4 ml/100 gm/min). Concurrent with their resolution of the seizure activity, both nimodipine and clonazepam reduced rCBF to near preseizure levels and preserved the rCBF response to
hypercarbia
which would otherwise have been abolished following prolonged seizure activity. Moreover, the effect of nimodipine on rCBF and seizures occurred without any prominent alterations in mean arterial blood pressure as compared to preseizure levels. These data support the proposition that a dihydropyridine Ca++ channel binding site may play a role in modulating paroxysmal neuronal activity, and suggest that this class of agents may reflect a novel group of antiepileptic drugs.
...
PMID:Effect of dihydropyridines and diphenylalkylamines on pentylenetetrazol-induced seizures and cerebral blood flow in cats. 361 73
Effects of s.c. doses of morphine and verapamil, alone and in combination, on arterial blood gases and pH, mean blood pressure and heart rate were assessed in partially restrained, awake Fischer-344 rats. As expected, morphine (4-16 mg/kg) produced a dose-dependent respiratory depression, as indicated by hypoxia,
hypercapnia
and acidosis.
Verapamil
, a calcium channel antagonist, alone (10 mg/kg) did not affect these parameters; however, it significantly attenuated and delayed the aforementioned effects of morphine. Morphine caused a slight increase in mean blood pressure, which was not dose dependent, whereas verapamil reduced blood pressure dramatically even in the presence of morphine. All groups showed some tachycardia, but rats treated with morphine alone showed the most pronounced increase in heart rate, which was antagonized by verapamil. The authors conclude that the interaction of verapamil with morphine's respiratory depressant effects differs from the previously reported potentiation of morphine's antinociceptive and hypothermic actions.
...
PMID:Interactions between verapamil and morphine on physiological parameters in rats. 372 97
