Use dependence of amiodarone during the sinus tachycardia of exercise in coronary artery disease

Electrocardiographic phenotype of exercise-induced arrhythmogenic cardiomyopathy: A retrospective observational study

Introduction

The right ventricle can be susceptible to pathologic alterations with exercise. This can cause changes to the ECG. Our aim was to identify the electrocardiographic phenotype of exercise induced (ExI) arrhythmogenic cardiomyopathy (ACM).

Methods

A retrospective analysis of ECGs at rest, peak exercise and 1 min of recovery in four groups of individuals was performed: Arrhythmogenic Cardiomyopathy with genetic confirmation (Gen-ACM; n = 16), (genetically negative) ExI-ACM (n = 15), control endurance athletes (End; n = 16) and sedentary individuals (Sed; n = 16). The occurrence of ventricular arrhythmias (VA) and, at each stage, QRS duration, Terminal Activation Delay (TAD), the ratio of the sum of the QRS durations in the right precordials (V1-V3) over that in the left precordials (V4-V6; R/L duration ratio), the presence of complete RBBB and T-wave inversion (TWI) beyond lead V2 were evaluated.

Results

At rest, complete RBBB was exclusively found in Gen-ACM (6%) and ExI-ACM (13%). No epsilon waves were identified. TWI beyond V2 was uniquely present in Gen-ACM (73%) and ExI-ACM (38%; p < 0.001). VA was present in Gen-ACM (88%); ExI-ACM (80%), End (25%) and Sed (19%; p < 0.001). The presence of R/L duration ratio of >1.2 and TAD ≥ 55 ms were not significantly different over the four groups (p = 0.584 and p = 0.218, respectively). At peak exercise the most striking finding was a significant decrease of the R/L duration ratio in individuals with ACM, which was the result of lateral precordial QRS prolongation.

Conclusion

ExI-ACM shares important ECG-features with Gen-ACM, suggesting a similar underlying pathogenesis regardless of the presence or absence of desmosomal mutations.

Detecting drug-induced prolongation of the QRS complex: new insights for cardiac safety assessment

BACKGROUND

Drugs slowing the conduction of the cardiac action potential and prolonging QRS complex duration by blocking the sodium current (I(Na)) may carry pro-arrhythmic risks. Due to the frequency-dependent block of I(Na), this study assesses whether activity-related spontaneous increases in heart rate (HR) occurring during standard dog telemetry studies can be used to optimise the detection of class I antiarrhythmic-induced QRS prolongation.

METHODS

Telemetered dogs were orally dosed with quinidine (class Ia), mexiletine (class Ib) or flecainide (class Ic). QRS duration was determined standardly (5 beats averaged at rest) but also prior to and at the plateau of each acute increase in HR (3 beats averaged at steady state), and averaged over 1h period from 1h pre-dose to 5h post-dose.

RESULTS

Compared to time-matched vehicle, at rest, only quinidine and flecainide induced increases in QRS duration (E(max) 13% and 20% respectively, P<0.01-0.001) whereas mexiletine had no effect. Importantly, the increase in QRS duration was enhanced at peak HR with an additional effect of +0.7 ± 0.5 ms (quinidine, NS), +1.8 ± 0.8 ms (mexiletine, P<0.05) and +2.8 ± 0.8 ms (flecainide, P<0.01) (calculated as QRS at basal HR-QRS at high HR).

CONCLUSION

Electrocardiogram recordings during elevated HR, not considered during routine analysis optimised for detecting QT prolongation, can be used to sensitise the detection of QRS prolongation. This could prove useful when borderline QRS effects are detected. Analysing during acute increases in HR could also be useful for detecting drug-induced effects on other aspects of cardiac function.

A cardiovascular monitoring system used in conscious cynomolgus monkeys for regulatory safety pharmacology: Part 2: Pharmacological validation

INTRODUCTION

This project addresses the validation study design of a test system using a telemetered non-human primate model for cardiovascular safety pharmacology evaluation.

METHODS

In addition to non-pharmacological validation including installation and operation qualifications, performance qualification (locomotor activity and cardiovascular evaluations) was completed on free-moving cynomolgus monkeys by quantifying the degree of cardiovascular response measured by the telemetric device to various positive control drugs following their intravenous administration. Remifentanil (0.0005, 0.001, 0.002, 0.004, 0.008 and 0.016 mg/kg) was given to induce bradycardia and hypotension. Medetomidine (0.04 mg/kg) was used to induce an initial phase of hypertension followed by hypotension and bradycardia. Esmolol (0.5, 1.0 and 2.0 mg/kg) was used to induce bradycardia. Dopamine (0.002, 0.008, 0.01, 0.02, 0.03 and 0.05 mg/kg/min) was infused over 30 min to induce an increase in arterial and pulse pressures and tachycardia. Amiodarone (0.4, 0.8 and 1.6 mg/kg/min) was infused over 10 min to induce QT interval prolongation. Potassium chloride (0.08 mEq/kg/min) was infused for periods of less than 30 min to induce electrocardiographic (EKG) changes characteristic of hyperkalemia. Reliability was evaluated over 60 days.

RESULTS

Monitoring with a reference methodology and the telemetry system was important in order to evaluate precision and accuracy of the test system. Positive control drugs produced a wide range of cardiovascular effects with different amplitudes, which were useful in identification of the limits of the test system.

DISCUSSION

Reference monitoring methods and selection of a battery of positive control drugs are important to ensure proper test system validation. Drugs inducing not only QT prolongation but also positive and negative chronotropic effects, positive and negative systemic arterial pressure changes and ECG morphology alterations were useful to identify test system limitations during performance qualification. ECG data processing at significantly elevated heart rates revealed that a trained observer should review all cardiac cycles evaluated by computer.

Electrophysiological effects of dronedarone (SR33589), a noniodinated benzofuran derivative, in the rabbit heart : comparison with amiodarone

BACKGROUND

To overcome the side effects of amiodarone (AM), its noniodinated analogue, dronedarone (SR), was synthesized. In this study, its electrophysiological effects were compared with those of AM in rabbit hearts.

METHODS AND RESULTS

Five animal groups (n=7 each) for 3 weeks received daily oral treatment of 1 of these regimens: (1) control, vehicle only; (2) AM 50 mg/kg (AM50); (3) AM 100 mg/kg (AM100); (4) SR 50 mg/kg (SR50); and (5) SR 100 mg/kg (SR100). ECGs were recorded before drug and at 3 weeks of drug before euthanasia. Action potentials were recorded from isolated papillary muscle and sinoatrial node by microelectrode techniques. The short-term effects were studied in controls (n=5) at various concentrations of SR (0 to 10 micromol/L) in tissue bath. Action potential duration at 50% (APD(50)) and 90% (APD(90)) repolarization and upstroke dV/dt (V(max)) at various cycle lengths were compared by ANOVA with repeated measures. Compared with control, AM and SR increased RR, QT, and QTc intervals (P<0.0001 for all). Ventricular APD(50) and APD(90) were lengthened by 20% to 49% as a function of dose (P<0.005 to <0.0001) and cycle length (P<0.001). SR100 effects were greater than those of AM100 (P<0.002). V(max) was decreased by both AM100 (P<0.0001) and SR100 (P<0.01). Sinoatrial node automaticity was slowed in treated groups compared with that of the control group (P<0.0001 for all).

CONCLUSIONS

The electrophysiological effects of dronedarone are similar to those of AM but more potent, despite deletion of iodine from its molecular structure, a finding of importance for the development of future class III antiarrhythmic compounds.

Parenteral antiarrhythmic drug therapy in ventricular tachycardia/ventricular fibrillation: evolving role of class III agents--focus on amiodarone

More effective intravenous antiarrhythmic agents are required for treatment of patients with refractory malignant ventricular arrhythmias. More recently, a great deal of interest has been focused on use of intravenous amiodarone for these patients. Uncontrolled early studies showed that intravenous amiodarone was effective in 42% to 81% of treated patients. Recent large cooperative trials have documented the efficacy of intravenous amiodarone in these patients and have shown an efficacy comparable to bretylium in patients with refractory sustained ventricular tachycardia or fibrillation.

Acute effects of amiodarone on membrane properties, refractoriness, and conduction in guinea pig papillary muscles

Amiodarone has potent and complex antiarrhythmic effects associated with a rare incidence of proarrhythmia. For a comprehensive understanding of its antiarrhythmic mechanisms in the same preparations, amiodarone (50 microM) was employed as it would be in the clinical setting and applied to guinea pig papillary muscles impaled by microelectrodes, paced at different rates, and superfused with various concentrations of potassium ([K]e). Amiodarone exerted complex actions, as follows: (1) The maximum rate of rise (Vmax) of the fast action potential (i.e., [K]e = 5.4-9.0 mM) as well as that of the slow action potential (i.e., [K]e = 15.0 mM in the presence of 1.0 microM isoproterenol) was suppressed in a rate-dependent manner. (2) Amiodarone exhibited a rate- and [K]e-dependent increase in the ratio of effective refractory period vs action potential duration at 90% repolarization (ERP/APD90), disclosing post-repolarization refractoriness. (3) Amiodarone had no effect on passive cable factors, such as threshold current and tissue resistance, during propagation. These versatile electrophysiological effects of amiodarone may contribute to its unique antiarrhythmic effects, as well as the low incidence of proarrhythmia with this drug.

Pharmacokinetics and regional electrophysiological effects of intracoronary amiodarone administration

BACKGROUND

The reason for the delay in onset of the electrophysiological effects and antiarrhythmic efficacy of amiodarone is not clear. The relation between the development of the electrophysiological effects of amiodarone and its myocardial concentration is unknown. We therefore examined the time course of development of electrophysiological effects during intracoronary infusion of amiodarone and related these changes to myocardial concentrations.

METHODS AND RESULTS

Amiodarone (0.139 mg/min) or normal saline was infused for 10 hours into the proximal left anterior descending coronary artery of 24 open-chest dogs. Nineteen animals received intracoronary amiodarone and 5 received normal saline (control group). Ten of the 19 that received amiodarone underwent electrophysiological study (amio-EPS group). Sixteen of the 19, including 7 from the amio-EPS group, underwent pharmacological study (PS group). In the amio-EPS group during pacing at a cycle length of 300 ms, changes in conduction velocities in drug-exposed myocardium referenced to nonexposed myocardium at 1 hour of infusion were -3.7% in the longitudinal direction (P = NS) and -7.2% in the transverse direction (P < .05); at 3 hours, -12.9% (P < .05) and -9.1% (P < .05); and at 9 hours, -32.9% (P < .02) and -31.7% (P < .01). These changes were dependent on amiodarone concentration (R2 = .83). There was also an obvious rate-dependent effect that was more pronounced for transverse conduction velocities. This effect was also dependent on amiodarone concentration. In the PS group, amiodarone levels in the drug-exposed myocardium increased from a mean of 5.95 microgram/g at 15 minutes of infusion to 188.88 microgram/g at the 10th hour. This increase was time dependent (R2 = .91). In the nonexposed myocardium, amiodarone levels were always low and increased minimally over time from a mean of 2.68 to 14.45 microgram/g. This increase was also time dependent (R2 = .97).

CONCLUSIONS

Selective intracoronary amiodarone infusion resulted in selective drug accumulation and concomitant time-dependent reduction of myocardial conduction velocity. There was a significant correlation between the extent of reduction of conduction velocity and myocardial amiodarone concentration but not coronary arterial or systemic concentration. Repolarization was not significantly altered.

Use-dependent prolongation of ventricular tachycardia cycle length by type I antiarrhythmic drugs in humans

BACKGROUND

Type I antiarrhythmic drugs block the cardiac sodium channel in a use-dependent fashion. This use-dependent behavior causes increased drug binding and consequently increased sodium channel blockade at faster stimulation rates. Importantly, the kinetics of drug association and dissociation from the sodium channel differ for each type I antiarrhythmic drug.

METHODS AND RESULTS

Thirty-five patients receiving type I antiarrhythmic drugs for the treatment of sustained monomorphic ventricular tachycardia (VT) were studied before and after drug therapy. A total of 41 drug studies were performed (lidocaine, n = 10; procainamide, n = 16; flecainide, n = 15). Sustained monomorphic VT of an identical electrocardiographic morphology was induced during the control and follow-up drug studies. During the control study, there was no significant change in the VT cycle length over time. Compared with control, significant prolongation of the onset VT cycle length was observed after treatment with procainamide and flecainide (increase of 52 +/- 24 and 80 +/- 49 msec, respectively) but not after treatment with lidocaine (increase of 8 +/- 37 msec). Additional drug-induced prolongation of the VT cycle length occurred during a 40-second observation period. This secondary "use-dependent" cycle length prolongation contributed significantly to the steady-state VT cycle length during treatment with flecainide (increase of 82 +/- 34 msec; p < 0.0001). Although a use-dependent increase in VT cycle length was observed with procainamide and lidocaine, the increase was not statistically significant (increase of 12 +/- 15 and 8 +/- 8 msec, respectively). The estimated time constants for the onset of use-dependent VT cycle length prolongation were distinctly different for the three drugs. Flecainide's prolongation of the VT cycle length occurred slowly, with an estimated time constant of 12.5 +/- 5.0 seconds. In contrast, the time course of VT cycle length prolongation was rapid during treatment with lidocaine and intermediate during treatment with procainamide (time constants of 0.52 +/- 0.51 and 4.0 +/- 1.3 seconds, respectively).

CONCLUSIONS

Use-dependent prolongation of VT cycle length during treatment with type I antiarrhythmic drugs was observed in humans. This effect was clinically significant during treatment with flecainide (i.e., the use-dependent slowing of the heart rate improved the hemodynamic tolerance of the arrhythmia). Finally, the estimated time constants for the use-dependent prolongation of VT cycle length by the three test drugs are similar to their reported in vitro time constants for use-dependent sodium channel blockade.

Effects of long-term oral administration of amiodarone on the electromechanical performance of rabbit ventricular muscle

1. The effects of long-term administration of oral amiodarone on transmembrane action potential and contraction of ventricular muscle were investigated in rabbits. 2. ECGs of rabbits that received oral amiodarone 50 mg or 100 mg kg-1 daily for 4 weeks, showed a significant prolongation of RR, QT and corrected QT (QTc) intervals, whereas PQ and QRS were unaffected. Serum and myocardial tissue amiodarone concentrations were 0.14-0.18 micrograms ml-1 and 1.47-3.63 micrograms g-1 wet wt. respectively. 3. Right ventricular papillary muscles isolated from treated rabbits were characterized by a moderate prolongation of action potential duration (APD) compared with controls. A slight decrease of the maximum upstroke velocity (Vmax) was also observed at the higher dose. The APD prolongation by chronic amiodarone, unlike acute effects of sotalol, E-4031, Cs+ and 4-aminopyridine, did not show marked reverse use-dependence. 4. APD and Vmax restitution following slow basic stimuli (0.03 Hz) were unaffected by chronic treatment with amiodarone. 5. Acute application of amiodarone (10 microM) caused a significant decrease in APD and developed tension, as well as a marked use-dependent Vmax inhibition with fast recovery kinetics. 6. These findings suggest that a major and consistent electro-physiological effect of chronic amiodarone is repolarization delay (Class-III action) showing minimal frequency-dependence. However, when amiodarone above a certain concentration is present in the extracellular space, a fast kinetic Class-I action would be added as an acute effect.

Rate-dependent effects of diltiazem on human atrioventricular nodal properties

BACKGROUND

Tachycardia enhances the channel-blocking effects of antiarrhythmic drugs. In contrast to the extensive data regarding the rate-dependent effects of sodium channel blockers in humans, little is known about the frequency-dependent effects of calcium channel blockers on human atrioventricular (AV) nodal properties. Accordingly, the purpose of this study was to evaluate the importance of heart rate in modulating the electrophysiological effects of diltiazem in humans.

METHODS AND RESULTS

Electrophysiological studies were performed in 25 patients. Sinus node, atrial, and AV nodal function were evaluated at multiple atrial rates under control conditions and after administration of one of three intravenous doses of diltiazem designed to produce low, intermediate, and high stable plasma concentrations (designated doses 1, 2, and 3, respectively). Results were analyzed in terms of the longest and shortest cycle lengths obtainable in each patient under control and drug conditions. Plasma concentrations of diltiazem were stable and averaged 43 +/- 4, 73 +/- 6, and 136 +/- 11 ng/ml for doses 1, 2, and 3, respectively. Sinus node recovery time, intra-atrial conduction time, atrial effective refractory period, and HV interval were unaffected by diltiazem infusion. Effects of diltiazem were limited to changes in AV nodal parameters. Stable, dose-dependent increases in Wenckebach cycle length were observed after all three doses of diltiazem (increases of 54 +/- 13, 84 +/- 18, and 174 +/- 33 msec for doses 1, 2, and 3, respectively). Small nonsignificant increases in AH interval and atrioventricular effective refractory period (AVERP) were observed after dose 1 of diltiazem. At long cycle lengths, diltiazem caused modest increases in AH interval (3 +/- 4 and 25 +/- 8 msec for doses 2 and 3, respectively) and AVERP (36 +/- 12 and 70 +/- 25 msec). Drug effects were far greater at short cycle lengths (45 +/- 17 msec, 58 +/- 12 msec for AH interval and 80 +/- 24 msec, 163 +/- 41 msec for AVERP; p less than 0.05 versus values at long cycle lengths). At rapid rates, effects of diltiazem on AVERP substantially exceeded those on AV conduction, a result that could account for the beneficial effects of diltiazem during paroxysmal AV reentrant tachycardia by decreasing the excitable gap.

CONCLUSIONS

Depressant effects of diltiazem on human AV nodal function are highly dependent on atrial rate; the rate-dependent actions on AV nodal refractoriness probably contribute to beneficial effects of diltiazem in patients with supraventricular arrhythmias.

Kinetics of use-dependent ventricular conduction slowing by antiarrhythmic drugs in humans

BACKGROUND

Rate-dependent conduction slowing by class I antiarrhythmic agents has clinically important consequences. Class I drugs are known to produce use-dependent sodium channel blockade. If rate-dependent conduction slowing by class I agents is due to sodium channel blocking actions, the kinetics of conduction slowing should be similar to those of depression of sodium current indexes in vitro. The purpose of the present investigation was to study the onset time course of ventricular conduction slowing caused by a variety of class I agents in humans.

METHODS AND RESULTS

Twenty-seven patients undergoing electrophysiological evaluation for antiarrhythmic therapy were studied. Changes in QRS duration at initiation of ventricular pacing at cycle lengths of 400 and 500 msec were used to evaluate the kinetics of drug action. Mean time constants for each drug were similar to values for Vmax depression reported in vitro studies: flecainide, 24.9 +/- 11.6 beats in eight patients (versus 34.5 beats reported for Vmax block); propafenone, 17.8 +/- 6.9 beats in five patients (versus 8.4-20.8 beats); quinidine, 7.0 +/- 2.4 beats in six patients (versus 5.6-6.2 beats); and amiodarone, 3.6 +/- 2.0 beats for eight patients (versus 3.0 beats). Time constants were significantly different among the various drugs tested (p = 0.0002 at a cycle length of 400 msec; p = 0.002 at 500 msec), and there was a strong correlation (r = 0.89, p less than 0.0001) between values obtained at a cycle length of 400 msec and those at a cycle length of 500 msec. No rate-dependent changes in QRS duration were seen at onset of ventricular pacing among eight age- and disease-matched control patients not taking class I antiarrhythmic drugs, including three patients subsequently showing such changes during type I antiarrhythmic drug therapy.

CONCLUSIONS

We conclude that class I agents produce use-dependent QRS prolongation in humans with characteristic kinetics for each agent that are similar to the kinetics of Vmax depression in vitro. These results suggest that rate-dependent ventricular conduction slowing by antiarrhythmic drugs in humans is due to use-dependent sodium channel blockade.

Amplification of flecainide-induced ventricular conduction slowing by exercise. A potentially significant clinical consequence of use-dependent sodium channel blockade

Proarrhythmic effects of flecainide acetate have been reported during exercise, but the mechanism for the arrhythmogenic interaction between flecainide and exercise is unknown. We hypothesized that the sinus tachycardia of exercise may enhance flecainide-induced conduction slowing by increasing use-dependent sodium channel blockade, thereby facilitating the occurrence of ventricular reentry. To evaluate the modulation of flecainide's effects by exercise, we studied 19 patients who were receiving therapeutic doses of flecainide for the treatment of cardiac arrhythmias. Sixteen patients underwent treadmill exercise testing by a modified Bruce protocol. During exercise, QRS duration increased progressively from 94 +/- 22 msec (mean +/- SD) at rest to 116 +/- 25 msec (p less than 0.001) at a mean heart rate increase of 84 +/- 32 beats/min. The patient with the greatest QRS increase developed a monomorphic ventricular tachycardia at peak exercise. At rest, the QRS duration after treatment with flecainide increased 12.1 +/- 10.0% compared with the pretreatment value, and with exercise, the QRS duration increased by a further 28.1 +/- 17.0% compared with the predrug value. We found that the best predictor of further exercise-induced QRS slowing was the change in QRS duration produced by flecainide at rest (r = 0.76, p = 0.001). In an age- and disease-matched control group, the QRS duration did not change during exercise that caused a similar heart rate increase.(ABSTRACT TRUNCATED AT 250 WORDS)

Rate-related electrophysiologic effects of long-term administration of amiodarone on canine ventricular myocardium in vivo

The electrophysiologic effects of amiodarone were examined in 13 dogs that received 30 g amiodarone orally during 3 weeks and compared with 13 control dogs that did not receive amiodarone. Longitudinal and transverse epicardial conduction velocities were estimated with a square array of 64 closely spaced electrodes and a computer-assisted acquisition and analysis system. Amiodarone caused a rate-dependent decrease in conduction velocity with a slightly greater effect in the longitudinal direction of propagation. Rate-related depression of conduction velocity developed rapidly after abrupt shortening of the pacing cycle length; 67% of the change occurred between the first two beats of the rapid train, and little change occurred after the 10th beat. Recovery from use-dependent depression of conduction velocity was exponential with a mean time constant of 447 +/- 172 msec in the longitudinal direction and 452 +/- 265 msec in the transverse direction. Repolarization intervals, defined as the interval between the activation time and the repolarization time in the unipolar electrograms, correlated highly with refractory period determinations in the absence and presence of amiodarone at each cycle length tested. The increase in repolarization intervals and refractory periods resulting from amiodarone treatment did not vary with cycle length. Amiodarone treatment also resulted in a significant rate-related reduction in systolic blood pressure. The systolic blood pressure in the group that received amiodarone decreased by a mean of 50 +/- 23% between steady-state pacing cycle lengths of 1,000 and 200 msec, whereas the corresponding decrease in the control group was 21 +/- 32% (p less than 0.05). Plasma and myocardial amiodarone and desethylamiodarone levels were comparable to those observed clinically. We conclude that long-term amiodarone administration causes rate-dependent reductions in conduction velocity and blood pressure and causes rate-independent increases in repolarization intervals.