Summary
The effects of cibenzoline, rightly known as a sodium channel inhibitor (class IC antiarrhythmic drug), were investigated in anaesthetized, closed-chest dogs, on conduction in the contractile fibres, ventricular and atrial, the His-Purkinje system and the atrioventricular node. In ventricular muscle, conduction time was measured between base and apex by two endocavitary electrodes. The other conduction times were obtained from the recording of the His bundle potentials. In addition, effective refractory period was determined by the extrastimulus method in ventricular and atrial muscle and in the atrioventricular node, and sinus rate monitored in the intervals of pacing periods. In the absence of vagal tone, cibenzoline in 4 mg - kg−1 dose prolonged conduction times in the ventricular contractile tissue, His-Purkinje system and atrial contractile tissue to a large extent, but decreasingly from the former to the latter. This prolongation was antagonized by hypernatremia (174 mmol. 1−1). In contrast, conduction time in the atrioventricular node, effective refractory periods and sinus rate were very little influenced. In the presence of vagal tone, the prolongation of conduction times in the ventricular contractile tissue, His-Purkinje system and atrial contractile tissue did not differ substantially from previously. It was the same for ventricular effective refractory period. But atrial effective refractory period was then considerably lengthened, while conduction time and effective refractory period in the atrioventricular node were greatly shortened and sinus rate notably accelerated. All these latter changes, independent of any hypotension which might have reflexly reduced vagal tone, and counteracted by hypercalcaemia (38 mmol. 1−1), are probably to be imputed to some blockade of calcium channel the role of which becomes preeminent in the atrial electrogenesis under vagal tone.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Badui E, Garcia-Rubi D, Estanol B (1981) Inadvertent massive lidocaine overdose causing temporary complete heart block in myocardial infarction. Am Heart J 102:801–803
Bailey JC, Greenspan K, Elizari MV, Anderson GJ, Fisch C (1972) Effects of acetylcholine on automaticity and conduction in the proximal portion of the His-Purkinje specialized conduction system of the dog. Circ Res 30:210–216
Bertrix L, Bui-Xuan B, Lang J, Bouzouita K, Timour Q, Faucon G (1983) Influence of the restoration of vagal tone by intracisternal injection of dextromoramide on the cardiac effects of the antiarrhythmic drugs. J Pharmacol (Paris) 14:361–372
Bertrix L, Lang J, Lakhal M, Timour Q, Faucon G (1985) Biphasic effect of a gradual rise in plasma calcium concentration on vulnerability to fibrillation. Naunyn-Schmiedeberg's Arch Pharmacol 329:182–187
Boyett MR, Fedida D (1983) A simple model of ion concentration changes in the heart during repetitive activity. J Physiol (Loud) 342:52–53
Boyett MR, Jewell BR (1980) Analysis of the effects of changes in rate and rhythm upon electrical activity of the heart. Prog Biophys Mol Biol 36:1–52
Brown H, Kimura J, Noble S (1981) Calcium entry dependent inactivation of the slow inward current in the rabbit sine-atrial node. J Physiol (Lond) 320:11
Browne KF, Prystowsky EN, Zipes DP, Chilson DA, Heger JJ (1984) Clinical efficacy and electrophysiologic effects of cibenzoline therapy in patients with ventricular arrhythmias. J Amer Coll Cardiol 3:857–864
Eckert R, Tillotson DL, Brehm P (1981) Calcium-mediated control of Ca and K currents. Fed Proc 40:2226–2232
Farges J-P, Faucon G, Lievre M, Ollagnier M (1978) Relationship between atrial and ventricular rates of fibrillation and cardiac contractile tissue effective refractory periods in the dog. Br J Pharmacol 63: 587–591
Furuta T, Toyama J, Yamada K (1983) Comparative study of cibenzoline and disopyramide on fast channel blocking and anticholinergic action in isolated guinea-pig cardiac muscle. Environm Med 27:99–104
Gindler EM, King JD (1972) Rapid colorimetric determination of calcium in biologic fluids with methyl thymol blue. Am J Clin Pathol 58:376–383
Harris EJ, Hutter OF (1956) The action of acetylcholine on the movements of potassium ions in the sinus venosus of the heart. J Physiol (Lond) 133:58–59
Hodess AB, Follansbee WP, Spear JF, Moore EN (1979) Electrophysiological effects of a new antiarrhythmic agent, flecainide, on the intact canine heart. J Cardiovasc Pharmacol 1:427–439
Hondeghem LM, Katzung BG (1977) Time- and voltage-dependent interactions of antiarrhythmic drugs with cardiac sodium channels. Biochim Biophys Acta 472:373–398
Kline RP, Morad M (1978) Potassium efflux in heart muscle during activity. Extracellular accumulation and its implications. J Physiol Lond 280:537–558
Lang J, Timour Chah Q, Aupetit J-F, Lancon J-P, Lakhal M, Faucon G (1988a) Frequency- and time-dependent depression of ventricular distal conduction by two novel antiarrhythmic drugs, cibenzoline and flecainide. Arch Int Pharmacodyn Ther 293:97–108
Lang J, Timour Chah Q, Charve P, Aupetit J-F, El Chebly M, Faucon G (1987) Role of calcium in the rate-dependent depression of atrioventricular nodal conduction in the dog heart under vagal influence. Int J Cardiol 15:65–76
Lang J, Timour Chah Q, El Chebly M, Faucon G (1986) Effect of gradual rise in plasma calcium concentration on the impairment of atrioventricular nodal conduction due to verapamil. J Cardiovasc Pharmacol 8:6–13
Lang J, Timour Q, Lancon J-P, Aupetit J-F, Faucon G (1988b) Biphasic dose-response relationship observed with Bay k 8644 on atrioventricular nodal conduction inhibited by verapamil. Naunyn-Schmiedeberg's Arch Pharmacol 338:196–201
Lang J, Timour Q, Lancon J-P, Aupetit J-F, Faucon G (1989) Effects of isoproterenol and propranolol on pharmacologically induced depression of intraventricular conduction. Fund Clin Pharmacol 3:281–294
Li T,Vassalle M (1984) The negative inotropic effect of calcium overload in cardiac Purkinje fibers. J Mol Cell Cardiol 16:65–77
Lipsius SL, Vassalle M (1977) Effects of acetylcholine in potassium movements in the guinea-pig sinus node. J Pharmacol Exp Ther 201:669 -677
Loeb JM, de Tarnowsky JM (1984) Acetylcholine calcium interactions in the canine atrium and sinus node. Am Heart J 107:1161–1168
Loomis TA, Krop S (1955) Auricular fibrillation induced and maintained in animals by acetylcholine or vagal stimulation. Circ Res 3:390–396
Marban E, Tsien RW (1981) Is the slow inward calcium current of heart muscle inactivated by calcium? Biophys J 33:143a
Masse C, Cazes M, Sassine A (1984) Effects of cibenzoline, a novel antiarrhythmic drug, on action potential and transmembrane currents in frog atrial muscle. Arch Int Pharmacodyn Ther 269:219–235
Millar JS, Vaughan-Williams EM (1982) Effects on rabbit nodal, atrial, ventricular and Purkinje cell potentials of a new antiarrhythmic drug, cibenzoline, which protects against action potential shortening in hypoxia. Br J Pharmacol 75:469–478
Olsson SB, Edvardsson N (1981) Clinical electrophysiologic study of antiarrhythmic properties of flecainide: acute intraventricular delayed conduction and prolonged repolarization in regular paced and premature beats using intracardiac monophasic action potentials with programmed stimulation. Am Heart J 102:864–870
Paes de Carvalho A, Hoffman BF, de Paula Carvalho M (1969) Two components of the cardiac action potential. I. Voltage-time course and the effects of acetylcholine on atrial and nodal cells of the rabbit. J Gen Physiol 54:607–635
Reuter H (1984) Ion channels in cardiac cell membranes. Ann Rev Physiol 46:473–484
Sassine A, Masse C, Dufour A, Hirsch J-L, Cazes M, Puech P (1984) Cardiac electrophysiological effects of cibenzoline by acute and chronic administration in the anaesthetized dog. Arch Int Pharmacodyn Ther 269:201–218
Timour Chah Q, Bertrix L, Bouzouita K, Lang J, Faucon G (1983a) Study of the ventricular antifibrillatory effects of calcium channel blocking agents in comparison with lidocaine on canine normal heart in situ. Arch Int Pharmacodyn Ther 261:238–248
Timour Chah Q, Bertrix L, Lang J, Bouzouita K, Faucon G (1983b) Enhancement by Ca2+ ions of cholinergic effects on the canine heart in situ. Naunyn-Schmiedeberg's Arch Pharmacol 322: 59–64
Timour Chah Q, Lang J, Lakhal M, Bouzouita K, Bertix L, Faucon G (1983c) Blockade by verapamil of cholinergic effects on atrial specialized tissue in the anaesthetized dog. Cardiovasc Res 17:756–761
Author information
Authors and Affiliations
Additional information
Send offprint requests to Q. Timour at the above address
Rights and permissions
About this article
Cite this article
Timour, Q., Aupetit, JF., Loufoua-Moundanga, J. et al. Ventricular and atrial electrophysiological effects of a IC antiarrhythmic drug, cibenzoline, in the innervated dog heart. Naunyn-Schmiedeberg's Arch Pharmacol 340, 338–344 (1989). https://doi.org/10.1007/BF00168520
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00168520