Comparative electrophysiological effects of disopyramide and bepridil on rabbit atrial, papillary, and Purkinje tissue: modification by reduced extracellular potassium

Why pacing frequency affects the production of early afterdepolarizations in cardiomyocytes: An explanation revealed by slow-fast analysis of a minimal model

Early afterdepolarizations (EADs) are pathological voltage oscillations in cardiomyocytes that have been observed in response to a number of pharmacological agents and disease conditions. Phase-2 EADs consist of small voltage fluctuations during the plateau of an action potential, typically under conditions in which the action potential is elongated. Although a single-cell behavior, EADs can lead to tissue-level arrhythmias. Much is currently known about the biophysical mechanisms (i.e., the roles of ion channels and intracellular Ca^{2+} stores) for the various forms of EADs, due partially to the development and analysis of mathematical models. This includes the application of slow-fast analysis, which takes advantage of timescale separation inherent in the system to simplify its analysis. We take this further, using a minimal three-dimensional model to demonstrate that phase-2 EADs are canards formed in the neighborhood of a folded node singularity. This allows us to predict the number of EADs that can be produced for a given parameter set, and provides guidance on parameter changes that facilitate or inhibit EAD production. With this approach, we demonstrate why periodic stimulation, as occurs in intact heart, preferentially facilitates EAD production when applied at low frequencies. We also explain the origin of complex alternan dynamics that can occur with intermediate-frequency stimulation, in which varying numbers of EADs are produced with each pulse. These revelations fall out naturally from an understanding of folded node singularities, but are difficult to glean from knowledge of the biophysical mechanism for EADs alone. Therefore, understanding the canard mechanism is a useful complement to understanding of the biophysical mechanism that has been developed over years of experimental and computational investigations.

L-type calcium current reactivation contributes to arrhythmogenesis associated with action potential triangulation

INTRODUCTION

The morphology of the mammalian cardiac action potential (AP) is an important factor in the susceptibility to drug-induced early afterdepolarizations (EADs) that may initiate torsade de pointes (TdP). AP triangulation has been shown to be an important predictor of drug-induced TdP.

METHODS AND RESULTS

APs from guinea pig and rabbit left ventricular single myocytes were recorded using a microelectrode-recording technique. I(Ca-L) currents were recorded in ventricular myocytes of guinea pig and rabbit using patch-clamping technique. At a stimulus frequency of 0.5 Hz, guinea pig ventricular myocytes displayed a square-like AP, whereas rabbit ventricular myocytes exhibited a triangle-like AP. Dofetilide-induced EADs were observed only in rabbit ventricular myocytes. Under the guinea pig AP clamping condition, the normalized I(Ca-L) instant reactivation currents in guinea pig and rabbit myocytes at voltages of -40 mV were 0.13 +/- 0.01 and 0.14 +/- 0.01, respectively. However, when rabbit AP served as the first clamping voltage, the normalized I(Ca-L) reactivation currents at -40 mV in guinea pig and rabbit myocytes were 0.20 +/- 0.01, 0.21 +/- 0.01, respectively, indicating that the I(Ca-L) recovery from inactivation in the rabbit triangular AP condition was significantly faster than in the guinea pig square AP condition. Comparison of the voltage clamp using the triangular waveform with the square waveform further confirmed that triangulation accelerates I(Ca-L) recovery from inactivation.

CONCLUSIONS

In rabbit ventricular myocardium, AP triangulation accelerates I(Ca-L) channel recovery from inactivation, leading to instability of the cell membrane potential during repolarization, which is capable of initiating TdP.

Comparison of the effects of NS-21 and terodiline on the QTc interval in dogs

1. NS-21 [(+/-)-4-diethylamino-1,1-dimethylbut-2-yn-1-yl 2-cyclohexyl-2-hydroxy-2-phenylacetate monohydrochloride monohydrate], its active metabolite, RCC-36, and terodiline, are mixed anticholinergic-Ca2+ antagonistic drugs. Among them, terodiline has been shown to cause torsade de pointes, a serious polymorphic ventricular tachycardia. It remains unknown, however, whether NS-21 or its active metabolite, RCC-36, produces torsade de pointes. 2. In anesthetized dogs, terodiline (10 mg/kg i.v.) significantly prolonged the QTc interval by 6-8%, an effect thought to be associated with torsade de pointes. In contrast, neither NS-21 nor RCC-36 (10 mg/kg i.v.) prolonged the QTc interval; therefore NS-21 is unlikely to cause ventricular tachyarrhythmias, such as those associated with terodiline. 3. The effects of NS-21, RCC-36 and terodiline on the action potential were investigated in guinea pig papillary muscle. However, none of these drugs prolonged the duration of the action potential, although only terodiline caused the muscle preparation to lose its excitability.

Bepridil prolongs the action potential duration of guinea pig ventricular muscle only at rapid rates of stimulation

1. We examined the electromechanical effects of the calcium antagonist, bepridil (1-20 microM), on isolated guinea pig ventricular muscles, driven at various stimulus frequencies (0.1, 0.5, 1, 2 and 5 Hz) in Tyrode's solution containing various K+ concentrations (1.4-43.2 mM). 2. Conventional microelectrode and tension-recording techniques were used. 3. We found that bepridil decreased the maximum upstroke velocity (Vmax) of the action potential with no change in the resting membrane potential (RMP). 4. The former effect depended on both stimulus frequency and the drug concentration used. 5. Bepridil lengthened the duration of the action potential at the level of 25% repolarization (APD25) at the highest frequency (5 Hz), but shortened it at lower frequencies (< or = 2 Hz). 6. The drug also lengthened the APD90 at the highest frequency (5 Hz) but without significant effect at lower frequencies (< or = 2 Hz). 7. Bepridil depolarized the RMP at relatively low extracellular K+ concentrations (< or = 2.7 mM), accompanied by a prolongation of APD90. 8. There were no such effects at much higher K+ concentrations (> or = 5.4 mM), and the drug markedly depressed the Vmax and the action potential amplitude. 9. The drug eliminated the positive staircase phenomenon of twitch contraction, in a concentration-dependent manner. 10. All these findings taken together suggest that bepridil prolongs the action potential duration by inhibiting outward potassium currents (IK and IK1), at rapid rates of stimulation (approximately 300/min), which is comparable to the physiological heart rate of a guinea pig. 11. The prolongation of APD seemed to be secondary to the bepridil-induced reduction of intracellular Ca2+ concentration, [Ca2+]i.

Metabolic, hemodynamic, and electrocardiographic responses to increased circulating adrenaline: effects of pretreatment with class 1 antiarrhythmics

In order to study the effects of treatment with class 1 antiarrhythmics on the metabolic, hemodynamic, and electrocardiographic responses to adrenaline, 12 healthy volunteers were infused on four occasions, after pretreatment with placebo, disopyramide, mexiletine, and flecainide, respectively, with adrenaline at a rate producing serum adrenaline concentrations comparable with those seen in acute myocardial infarction. After pretreatment with placebo adrenaline caused significant falls in serum potassium, serum magnesium, serum calcium, and serum phosphate and a significant increase in blood glucose. Adrenaline also caused a significant increase in heart rate and systolic blood pressure and a significant fall in diastolic blood pressure. On the electrocardiogram a significant prolongation of QTc duration and a flattening of the T-wave amplitude were seen. Pretreatment with disopyramide had no effect on the hemodynamic response to adrenaline but caused a significant prolongation of Qtc duration before the adrenaline infusion. Pretreatment with mexiletine was associated with a significantly greater fall in serum potassium during adrenaline infusion, and pretreatment with flecainide with a greater fall in serum magnesium, as compared with placebo pretreatment Flecainide also caused a significant prolongation of the QRS duration before adrenalin infusion, and after all the active pretreatments a prolongation of QRS duration was seen during adrenaline infusion. The metabolic and hemodynamic changes during adrenaline infusion may not only reduce the antiarrhythmic efficacy of antiarrhythmics but may also increase the risk of proarrhythmic effects in a clinical setting. These results may help to explain why treatment with antiarrhythmics seems to be without beneficial effect on mortality in post-myocardial infarction patients.

Effects of bepridil and CERM 4205 (ORG 30701) on the relation between cardiac cycle length and QT duration in healthy volunteers

Bepridil is a calcium antagonist that prolongs the duration of ventricular repolarization, whereas CERM 4205, another calcium antagonist, seems to be devoid of any effect on QT interval. The aim of this study was to compare the effects of bepridil and CERM 4205 on the QT-RR relation at different heart rates during rest and exercise and the results of pharmacologic tests designed to vary neurovegetative tone. Twelve healthy men (21 to 37 years) participated in a placebo-controlled, randomized, crossover, double-blind study and received either bepridil (200 mg/day twice daily) or CERM 4205 (200 mg/day twice daily), or matching placebo during three 14-day treatment periods at 2-week intervals. Bepridil, but not CERM 4205, caused a significant prolongation of resting QT interval. The RR-QT relation was monoexponential for all subjects during resting and exercising physiologic conditions and remained unchanged after 14 days with placebo or CERM 4205. Bepridil significantly shifted the relation upward, resulting in a rate-dependent QT prolongation that predominated during bradycardia. After isoprenaline, QT no longer adapted to changes in heart rate, whereas atropine resulted in a rate-dependent shortening in QT. These results suggest that bepridil and CERM 4205 exert different effects on ventricular repolarization, since only bepridil significantly prolonged QT duration. Bepridil-induced prolongation of QT increased at slow heart rates, which could explain the greater incidence of torsades de pointes in bradycardia.

Electrophysiological effects of bepridil and its quaternary derivative CERM 11888 in closed chest anaesthetized dogs: a comparison with verapamil and diltiazem

1. The electrophysiological effects of bepridil, its quaternary derivative, CERM 11888 (methylpyrrolidinium bromide) (both 2.5 mg kg-1 i.v.) and those of verapamil and diltiazem (0.2 mg kg-1 i.v.) were studied in closed chest anaesthetized dogs at doses used in clinical studies. 2. The four drugs caused a bradycardia with the following order of potency: bepridil greater than CERM 11888 greater than diltiazem greater than verapamil. 3. All the compounds slowed conduction in the AV node, increased the refractory period (RP) and decreased Wenckebach rates with the following order: verapamil much greater than diltiazem greater than bepridil greater than CERM 11888. 4. Verapamil and diltiazem did not affect conduction or the RP in atria while bepridil weakly slowed the former and markedly increased the latter. CERM 11888 caused a lengthening of RP but this was a delayed effect. 5. In the ventricle, bepridil and CERM 11888 caused a small increase in the QRS and a more pronounced increase in the RP. Both compounds increased QTc but did not modify HV. Verapamil and diltiazem had no significant effects at the ventricular level. 6. Our results confirm that the main sites of action of calcium antagonists are the SA and AV nodes. Bepridil has a broader spectrum of activity and also acts at the atrial and ventricular levels. A comparison of the effects of bepridil with those of its quaternary derivative suggests the involvement of an intracellular action in the electrophysiological effects of bepridil.

Bepridil: a pharmacological reappraisal of its potential beneficial effects in angina and tissue protection following ischemia

In this review the pharmacologic properties of the calcium antagonist bepridil have been reexamined, particularly the evidence for an intracellular locus of action for the drug. Physicochemical properties of bepridil show it to be highly lipophylic, rapidly and extensively taken up, and accumulated in certain tissues. Combined electrophysiologic and mechanical studies have provided convincing, but indirect, evidence for an intracellular action of bepridil in cardiac muscle. Bepridil also fulfills, to a greater or lesser extent, certain important pharmacologic criteria necessary for evoking an intracellular action of a drug in cardiac and vascular smooth muscle: 1. Responses to agonists known to utilize intracellular calcium in the response are inhibited to a similar extent to depolarization-induced K+ responses. 2. Phasic and tonic responses to noradrenaline in vascular tissues are not, or are only to a minor extent, differentially antagonized. 3. Responses to the calcium ionophore A 23187 are antagonized. 4. Activity is retained following removal of the cell membrane by surfactants. 5. Isolated enzyme systems (e.g., calmodulin, myosin light-chain kinase) are affected by the drug at similar concentrations to those that are effective in whole cells or tissues. Finally results obtained with bepridil in ischemic myocardium have been reviewed to ascertain whether its broader pharmacologic spectrum over the calcium-entry blockers is associated with enhanced tissue protective properties. Positive results with bepridil in hypoxic myocytes and ischemic myocardium distinguishes this drug from the classical antianginal agents verapamil, nifedipine, and diltiazem. It is suggested that bepridil, because of its paucity of hemodynamic effects, may be of special therapeutic interest in the management of silent ischemia where cellular mechanisms leading to cytoprotection are more desirable than strong hemodynamic activity.

Effects of bepridil on ventricular depolarization and repolarization of rabbit isolated hearts with particular reference to its possible proarrhythmic properties

1. Effects of bepridil on ventricular depolarization and repolarization sequences were examined in rabbit Langendorff-perfused hearts. 2. In distant bipolar electrograms (DBEs), bepridil, 10(-6) M, caused a significant prolongation of QT intervals. At 10(-5) M, the QT prolongation was further enhanced, and a significant prolongation of QRS duration was also observed. Polymorphous ventricular tachycardia was frequently induced by a single premature stimulus at the higher concentration. 3. In epicardial electrograms recorded through modified bipolar electrodes, bepridil, 10(-6) M, prolonged the interval from the peak negative deflection of the QRS complex to the apex of the T wave (Q-aT), which corresponded to the intracellular action potential duration at 90% repolarization (APD90). The Q-aT prolongation was larger in the base than in the apex, resulting in a marked distortion and dispersion of repolarization. The epicardial activation sequence was unaffected. 4. At 10(-5) M bepridil, the dispersion of repolarization was much more enhanced by activation delay in the epicardial surface. 5. These findings suggest that bepridil causes regionally different lengthening of APD in ventricular muscle leading to an increase in temporal dispersion of repolarization, and that this dispersion may be inducive for re-entrant arrhythmias when accompanied by slow conduction at toxic doses.