Drug response at electropharmacologic study in patients with ventricular tachyarrhythmias: the importance of ventricular refractoriness

Electrophysiologically guided amiodarone therapy versus the implantable cardioverter-defibrillator for sustained ventricular tachyarrhythmias after myocardial infarction: results of long-term follow-up

OBJECTIVES

We sought to compare the long-term survival rates of patients with sustained ventricular tachyarrhythmia after myocardial infarction (MI) who were treated according to the results of electrophysiological (EP) study either with amiodarone or an implantable cardioverter-defibrillator (ICD).

BACKGROUND

Patients with sustained ventricular tachyarrhythmias after MI are at high risk of sudden cardiac death (SCD). However, data comparing the long-term survival rates of patients treated with amiodarone or ICD, according to the results of EP testing, are lacking.

METHODS

Patients underwent a first EP study at baseline and a second one after a loading dose of amiodarone of 14 +/- 2.9 g. According to the results of the second EP study, patients were classified either as responders or non-responders to amiodarone; non-responders were eventually treated with an ICD.

RESULTS

Eighty-four consecutive patients with MI (78 men; 21-77 years old; mean left ventricular (LV) ejection fraction 36 +/- 11%) were consecutively included. Forty-three patients (51%) were responders, and 41 patients (49%) were non-responders to amiodarone therapy. During a mean follow-up period of 63 +/- 30 months, SCD and total mortality rates were significantly higher in the amiodarone-treated patients (p = 0.03 and 0.02, respectively).

CONCLUSIONS

The long-term survival of patients with sustained ventricular tachyarrhythmias after MI, with depressed LV function, is significantly better with an ICD than with amiodarone therapy, even when stratified according to the results of the EP study. These patients should benefit from early ICD placement, and any previous amiodarone treatment seems to have no additional value.

Combination IK1 and IKr channel blockade: no additive lowering of the defibrillation threshold

Selective blockade of the inward rectifier potassium channel I(K1) by barium, or of the rapidly activating delayed rectifier potassium channel I(Kr) by D,L-sotalol, prolongs repolarization and reduces the defibrillation threshold (DFT). This study hypothesized that combination I(K1) and I(Kr) channel block would produce concentration-dependent additive effects on DFT and ventricular refractoriness. A range of barium and D,L-sotalol concentrations, alone and in combination, were examined with respect to DFT, ventricular effective refractory period (VERP), and ventricular fibrillation cycle length (VFCL) in 133 Langendorff-perfused rabbit hearts. Barium produced a concentration-dependent reduction of DFT (-49+/-4%), with concentration-dependent increases in VERP (26+/-6%) and VFCL (42+/-18%). D,L-Sotalol produced a concentration-dependent lowering of DFT (-53+/-6%) with a concentration-dependent increase in VFCL (34+/-8%) but not VERP. Low (1.6 microM), intermediate (3.1 microM), and high (12.5 microM) barium concentrations combined with varying D,L-sotalol concentrations produced equal or smaller decreases in DFT compared with corresponding doses of barium or D,L-sotalol alone. Except at the lowest concentrations of barium (1.6 and 3.1 microM) (p < 0.05), there was no significant additive interaction between barium and D,L-sotalol on VERP or VFCL. Combination I(K1) and I(Kr) channel block by barium and D,L-sotalol does not produce additive reduction of DFT.

Can antiarrhythmic agents be selected based on mechanism of action?

When selecting an antiarrhythmic agent the clinician needs to be able to accurately predict the probability that a particular drug will serve its intended purpose in a given patient. This is difficult because of the complexity of variables which govern the relationship between drug administration and clinical outcome. The efficacy of a drug may potentially be predicted from its mechanism of action. At least two classifications of antiarrhythmic agents based on mechanism of action have been proposed. The Vaughan Williams classification is based on the predominant electrophysiological effects of a drug on the action potential. In the Sicilian Gambit approach, a number of potential targets ('vulnerable parameters') for drug action are identified and antiarrhythmic drugs or substances that affect cardiac electrophysiology are characterised by their actions on each of these. The usefulness of these classification systems in predicting antiarrhythmic drug efficacy are limited. Furthermore, in the Vaughan Williams classification not all drugs in the same class have identical effects, whereas some drugs in different classes have overlapping actions. The Sicilian Gambit requires in-depth knowledge regarding cellular and molecular targets of antiarrhythmic agents which may make it intimidating or simply impractical for regular clinical use. Surrogate measures such as 24-hour Holter monitoring and programmed electrical stimulation have been used to predict anti-arrhythmic drug efficacy. However, studies such the Cardiac Arrhythmia Suppression Trial (CAST) have shown that suppression of ventricular ectopy on Holter monitoring does not necessarily correlate with improved survival and may in fact be dangerous. Conversely, studies using programmed electrical stimulation to assess drug effect on variables such as tachycardia inducibility, refractory period and ventricular tachycardia cycle length show that suppression of tachycardia inducibility, prolongation of refractory period and prolongation of ventricular tachycardia cycle length, are all associated with reduced recurrence of tachycardia and possibly improved survival. The most practical use of the current classification systems applied to antiarrhythmic agents may be in their ability to predict with reasonable accuracy, the risk and type of proarrhythmia based on the mechanism of action of an agent.

Procainamide induced change of the width of the zone of entrainment and its relation to the inducibility of reentrant ventricular tachycardia

Procainamide depresses conduction velocity and prolongs refractoriness in myocardium responsible for reentrant VT, but the mechanism by which the induction of VT is suppressed after procainamide administration remains to be determined. In the present study, the relationship between electrophysiological parameters and the noninducibility of VT was assessed during procainamide therapy with a special reference to the change of an excitable gap. Clinically documented monomorphic sustained VT was induced in 30 patients and, utilizing the phenomenon of transient entrainment, the zone of entrainment was measured as the difference between the cycle length of VT and the longest paced cycle length interrupting VT (block cycle length) which was determined as the paced cycle length decreased in steps of 10 ms, and used as an index of the excitable gap. The effective refractory period was measured at the pacing site and the paced QRS duration was used as an index of the global conduction time in the ventricle. The cycle length of VT, the block cycle length, and the width of the zone of entrainment were determined and compared between the responders and nonresponders. In 15 patients, these parameters were determined at the intermediate dose and related to subsequent noninducibility at the final dose. At the final doses of procainamide, VT was suppressed in 8 (26.7%) of 30 patients. However, the cycle length of VT, the block cycle length, and the width of the zone of entrainment were unable to predict the drug efficacy, i.e., noninducibility. The change in the effective refractory period at the pacing site or the width of the paced QRS duration was not different between the responders and nonresponders. Among the variables, only the width of the zone of entrainment showed a significant narrowing in the responders at the intermediate dose of procainamide, and it was smaller than that of the nonresponders. The significant narrowing of the width of the zone of entrainment was associated with the subsequent noninducibility of VT at the final dose. The present study showed that the baseline cycle length of VT, the block cycle length, the drug induced change of the effective refractory period, or the paced QRS duration was not a predictor of the noninducibility after procainamide administration. However, a significant narrowing of the width of the zone of entrainment at the intermediate dose was associated with the noninducibility of VT at the final dose.

General principles of antiarrhythmic therapy for ventricular tachyarrhythmias

Sudden cardiac death due to ventricular arrhythmias is a significant cause of mortality in patients with structural heart disease. Over the past several decades, the introduction of new pharmacologic and nonpharmacologic therapy has expanded the treatment options available. This article will focus on the use of antiarrhythmic medication for the treatment of ventricular arrhythmias and will review the following: (1) treatment goals for various clinical populations, (2) the mechanisms of antiarrhythmic and proarrhythmic actions of antiarrhythmic medications, and (3) empiric versus guided pharmacologic therapy.

Electrophysiologic mechanisms of antiarrhythmic efficacy of a sotalol and class Ia drug combination: elimination of reverse use dependence

OBJECTIVES

We sought to determine the electrophysiologic mechanisms explaining the efficacy of combination therapy with DL-sotalol and a type Ia drug in the treatment of ventricular tachycardia (VT).

BACKGROUND

Combination antiarrhythmic drug therapy with low dose DL-sotalol plus a type Ia antiarrhythmic agent has been shown to prevent spontaneous and induced VT. The mechanisms underlying the efficacy of this drug combination have not been fully elucidated.

METHODS

We studied 32 patients with spontaneous sustained VT by using programmed electrical stimulation in the drug-free condition and after treatment with DL-sotalol (average dose [mean +/- SE] 151 +/- 8 mg/day) and a class Ia agent (quinidine, 1,337 +/- 59 mg/day, or procainamide, 2,083 +/- 327 mg/day). Sustained VT was induced in all patients at baseline study, and induction was reattempted during drug therapy. Monophasic action potential duration at 90% repolarization (APD90) and ventricular effective refractory period (ERP) were recorded with use of a contact electrode.

RESULTS

Ventricular ERP increased from 258 +/- 4 ms at baseline to 310 +/- 6 ms at a 600-ms drive cycle length (DCL600) with treatment (p < 0.001). APD90 increased from 288 +/- 6 ms by +10.1% at DCL600 and from 267 +/- 7 ms by +13.3% at a 400-ms drive cycle length (DCL400) (p < 0.001). Paced QRS duration increased from 141 +/- 3 to 158 +/- 6 ms at DCL400 (p < 0.05). At baseline, the shortest achieved coupling interval between successive propagated extrastimuli decreased progressively with respect to the first extrastimulus, following double and triple extrastimuli, at both DCL600 (-14.0% and -20.0%, respectively) and at DCL400 (-16.4% and -22.4%, respectively). This "peeling back" of refractoriness was attenuated on therapy with sotalol plus a class Ia antiarrhythmic agent to -6.7% and -10.5% (DCL600, p < 0.05), and -8.1%, -9.5% (DCL400, p < 0.05), for double and triple extrastimuli, respectively. The absolute prolongation of functional refractory periods by the drug combination increased with successive extrastimuli, from 55 +/- 6 ms for the V1V2 interval to 75 +/- 6 ms for V2V3 and 67 +/- 6 ms for V3V4 at DCL600, and from 51 +/- 5 ms for V1V2 to 69 +/- 6 ms for V2V3 and 74 +/- 7 ms for V3V4 at DCL400 (p < 0.001).

CONCLUSIONS

The combination of low dose sotalol and a class Ia agent greatly prolongs refractoriness. The magnitude of the effect increases at shorter coupling intervals.

Drug-induced narrowing of the width of the zone of entrainment as a predictor of the subsequent non-inducibility of reentrant ventricular tachycardia after an additional dose of an antiarrhythmic drug

BACKGROUND

The efficacy of drugs used to treat inducible monomorphic sustained ventricular tachycardia (VT) has been assessed by investigating their ability to suppress inducibility, but the mechanism of the drug action remains to be determined.

OBJECTIVES

To determine electrophysiological variables that predict inducibility, divided doses of class I antiarrhythmic drugs were given and their effects were analysed, particularly the ability of the final dose to suppress inducibility.

METHODS

The excitable gap was estimated by the zone of entrainment, which was defined as the difference between the cycle length of VT and the longest paced cycle length that interrupted VT during entrainment of VT with rapid pacing at paced cycle lengths in decrements of 10 ms. The cycle length of VT, the block cycle length, and the zone of entrainment were measured in the drug free state and after intermediate and final doses of procainamide, disopyramide, cibenzoline, and mexiletine.

RESULTS

Sustained monomorphic VT with a mean (SD) cycle length of 285 (43) ms was induced in 8 patients. It was entrained and interrupted at the block cycle length of 231 (31) ms. The width of the zone of entrainment was 54 (23) ms. In 8 studies VT was not inducible at final doses of procainamide in 4, cibenzoline in 1, and mexiletine in 3. In another 10 studies (procainamide in 4, disopyramide in 1, cibenzoline in 2, and mexiletine in 3), VT remained inducible at the intermediate dose and at the final dose. The cycle length of VT was prolonged to a similar degree in studies of effective and ineffective drugs, but the cycle length that blocked VT was longer at the intermediate dose of the effective drugs. Consequently, the width of the zone of entrainment was significantly narrowed at the intermediate dose of effective drugs and the width of the zone of entrainment was narrower than when ineffective drugs were given (22 (13) ms v 76 (18) or 75 (37) ms at the intermediate and final doses respectively (P < 0.02).

CONCLUSION

Drugs that narrowed the zone of entrainment were associated with non-inducibility of VT after the final dose of the drug was given. The baseline variables did not predict the responses to class I antiarrhythmic drugs.

Effect of sustained load on dispersion of ventricular repolarization and conduction time in the isolated intact rabbit heart

INTRODUCTION

It is well known that myocardial stretch can elicit ventricular arrhythmias in experimental models. However, previous reports have predominantly documented stretch-induced arrhythmias during short, pulsatile stretch. The arrhythmogenic mechanism of sustained static stretch is incompletely understood.

METHODS AND RESULTS

To examine the influence of sustained load on several electrophysiologic parameters, a latex balloon was placed into the left ventricle of ten isolated Langendorff-perfused rabbit hearts and filled with a neutral volume of fluid. The heart was paced from a catheter inside the right ventricle (apicoseptal endocardial position), and the following parameters were studied during steady-state pacing with a cycle length of 500 msec (S1) and during extrastimulation (S2, base drive of 8 beats): monophasic action potential (MAP) durations at 90% repolarization (APD90) from 5 to 6 epicardial electrodes located on both ventricles and one right ventricular endocardial contact electrode; dispersion of APD90 (range of MAP durations from all electrodes); effective refractory period (ERP) and longest activation time (pacing stimulus to MAP upstroke). After baseline recordings, the balloon inside the left ventricle was filled with a volume of 1.0 mL of fluid by means of a servo-controlled pump. The ERP was significantly shortened from 198 +/- 9 msec at baseline to 183 +/- 8 msec during sustained load (P < 0.03). Similarly, the average APD90 was shortened from 180 +/- 5 msec at baseline to 175 +/- 6 msec during sustained load (P < 0.006) with steady-state pacing and from 178 +/- 6 msec to 170 +/- 8 msec during premature extrastimulation (P < 0.03). At the same time, dispersion of APD90 was increased from 27 +/- 5 msec to 38 +/- 6 msec (P < 0.002) during steady-state pacing and from 28 +/- 4 msec to 38 +/- 6 msec (P = 0.013) during premature extrastimulation. The longest activation time among all MAP recordings was increased from 39 +/- 2 msec to 43 +/- 3 msec (P = 0.003) during steady-state pacing and from 56 +/- 6 msec to 69 +/- 6 msec during premature extrastimulation (P < 0.003).

CONCLUSIONS

Sustained load shortens the ERP and the mean APD90, and at the same time increases dispersion of APD90 and prolongs activation times. These findings provide additional insight into the arrhythmogenic mechanisms of sustained mechanical load.

Quinidine pharmacodynamics in patients with arrhythmia: effects of left ventricular function

OBJECTIVES

This study was undertaken to determine whether quinidine pharmacodynamics are altered in the presence of left ventricular dysfunction.

BACKGROUND

Left ventricular function is an independent predictor of antiarrhythmic drug efficacy. However, the effects of left ventricular dysfunction on the pharmacodynamics of antiarrhythmic drugs have not been studied extensively.

METHODS

Signal-averaged electrocardiograms were obtained and quinidine plasma concentrations measured during 24-h quinidine washout in 22 patients.

RESULTS

Linear quinidine concentration-effect relations were observed for QRS and QT intervals corrected for heart rate. The slopes of the concentration-effect relation describing changes in the corrected QT (QTc) interval were significantly higher in the group with left ventricular ejection fraction > or = 0.35 ([mean +/- SD] 29.5 +/- 11.2 ms/micrograms per ml) than in the group with a low left ventricular ejection fraction (15.7 +/- 9.7 ms/micrograms per ml, p = 0.001). The QRS concentration-effect relations were not different in the two groups. A significant linear correlation was observed between the slopes of the concentration-effect relations describing changes in QTc intervals and left ventricular ejection fraction (r = 0.7, p < 0.001). Nineteen patients with inducible ventricular tachycardia underwent serial electrophysiologic studies for evaluation of quinidine efficacy. Ventricular tachycardia could not be induced during quinidine therapy in eight patients. The slopes of the quinidine concentration-effect relations for QTc intervals were significantly higher in quinidine responders than in nonresponders (p < 0.05).

CONCLUSIONS

The effects of quinidine on ventricular repolarization are linearly related to left ventricular ejection fraction. Quinidine concentration-effect relations describing ventricular repolarization are associated with antiarrhythmic efficacy in patients with ventricular tachycardia.

Electrophysiologic effects of antiarrhythmic drug therapy in the prediction of successful suppression of induced ventricular tachycardia

Predictors of a successful outcome of serial electrophysiologic (EP) and drug studies have been identified from among baseline patient characteristics but not from among measures of baseline and drug-related EP effects. Identifying such predictors would be useful in explaining the mechanism of successful drug therapy and in guiding drug development and selection. We prospectively studied EP characteristics in 159 trials in 62 patients with ventricular tachycardia or ventricular fibrillation during antiarrhythmic therapy and compared EP measures between successful (n = 30) and failed trials (n = 129). The average age of the patients was 64 years (range 27 to 78 years); 82% were men and 18% women; and 87% had coronary artery disease. Measurements included R-R, QRS, and QT intervals during intrinsic rhythm and during pacing at cycle lengths of 600 of 400 msec; ventricular effective refractory periods (ERP) during pacing at cycle lengths of 600 and 400 msec; and changes in these measures, comparing treatment with drug-free baseline. Univariate predictors of success (in order of significance) included ERP600/QRS600, sotalol versus other drugs, ERP400/QRS400, delta ERP600, delta R-R, ERP600, QRS400 (negative association), delta ERP400, QRS600 (negative association), ERP400 (all p < 0.1). In two separate multivariate models, one for each drive cycle length, only the ratio ERP600/QRS600 (p = 0.01) in the first model and ERP400/QRS400 (p = 0.01) in the second model were significantly and independently associated with achieving noninducibility with drug therapy. Therefore measures of greater refractoriness and lesser delays in conduction velocity (ie, greater "wavelength") relate to drug success.(ABSTRACT TRUNCATED AT 250 WORDS)

Frequency-dependent electrophysiologic effects of amiodarone in humans

BACKGROUND

In general, antiarrhythmic agents that prolong the action potential duration (APD) have attenuated effects on repolarization at short cycle lengths (reverse frequency dependence), and this may limit their efficacy for controlling ventricular arrhythmias. The frequency-dependent effects of amiodarone on repolarization may differ from those of other antiarrhythmic agents and have not been determined in humans.

METHODS AND RESULTS

The frequency-dependent effects of amiodarone on repolarization and conduction were determined during electrophysiologic study in 19 patients at drug-free baseline and after 11 days of amiodarone loading (1621 +/- 162 mg/d, group A) and in 15 additional patients after > or = 1 year of chronic amiodarone therapy (380 +/- 56 mg/d, group B). The two groups were similar in all clinical characteristics. The ventricular APD at 90% repolarization (APD90), right ventricular effective refractory period (VERP), and QRS duration were determined at paced cycle lengths of 300 to 600 milliseconds. In group A, amiodarone significantly (10% to 13%, P < .001) increased the APD90 at all paced cycle lengths by approximately 30 milliseconds compared with baseline. Similarly, there were no frequency-dependent effects on the percent increase in VERP. However, there was greater amiodarone-induced prolongation of the VERP magnitude at longer paced cycle lengths than at shorter cycle lengths (P = .04), although the VERP remained significantly prolonged at the shortest paced cycle length (300 milliseconds) by 33 +/- 22 milliseconds (16.9% increase from baseline, P < .001). Amiodarone significantly (P < .01) increased the QRS duration at paced cycle lengths < or = 500 milliseconds by a maximum of 28% compared with baseline measurements. The increase in ventricular conduction time was frequency dependent (P < .01), consistent with significant sodium channel blockade. The VERP/APD90 ratio (determined at twice diastolic threshold) was significantly prolonged by amiodarone (as compared with baseline) at cycle lengths > or = 400 milliseconds, indicative of both time- and voltage-dependent effects on refractoriness. The increase in induced sustained ventricular tachycardia cycle length in group A patients after amiodarone loading was significantly correlated with the increase in VERP (r = .68, P = .044) but not with increases in QRS duration or APD90. In addition, there were no significant differences in frequency-dependent effects of amiodarone between groups A and B.

CONCLUSIONS

The frequency-dependent response of the electrophysiologic effects of amiodarone are similar after 11 days of loading or > or = 1 year of chronic therapy. Amiodarone does not exert frequency-dependent effects on ventricular repolarization; it prolongs refractoriness by both time- and voltage-dependent mechanisms and exerts frequency-dependent effects on ventricular conduction. The absence of amiodarone-induced reverse frequency-dependent effects on repolarization, together with its time-dependent effects on refractoriness may account in part for the high efficacy of the drug and its low propensity to cause torsade de pointes.

Antiarrhythmic effects of selective prolongation of refractoriness. Electrophysiologic actions of sematilide HCl in humans

BACKGROUND

Recent data have suggested that antiarrhythmic agents that act largely by delaying conduction may not be as effective in controlling ventricular arrhythmias as those that prolong repolarization. Recently, numerous "pure" class III agents have been developed.

METHODS AND RESULTS

The antiarrhythmic and electrophysiologic profiles of sematilide, a "pure" class III agent, were determined in 27 patients with clinical ventricular arrhythmias and inducible sustained ventricular tachycardia during electrophysiologic study. After treatment with oral sematilide (mean dose, 133 +/- 29 mg every 8 hours), the patients underwent repeat 24-hour ambulatory ECG monitoring and electrophysiologic study. The baseline sinus cycle length and QT, QTc, JT, and JTc intervals were significantly increased 8 to 17% by sematilide (P = .001 to .029). There were no changes in the PR or QRS intervals. Sematilide (at a paced cycle length of 600 ms) significantly increased the atrial effective refractory period (238 +/- 32 to 264 +/- 32 ms; 11 +/- 16% increase from baseline; P = .013), atrioventricular nodal effective refractory period (296 +/- 74 to 354 +/- 71 ms; 20 +/- 19%; P = .029), and right ventricular effective refractory period (252 +/- 25 to 281 +/- 30 ms; 12 +/- 8%; P < .001) but did not significantly change the PA or HV intervals, the corrected sinus node recovery time, or the Wenckebach cycle length. Determination of the frequency-dependent effects of sematilide (n = 10) on the right ventricular monophasic action potential duration (APD90) during ventricular pacing at cycle lengths of 600 to 300 ms revealed that the APD90 was significantly prolonged by sematilide during ventricular pacing at 600 to 350 ms (APD90 increase of 40 +/- 17, 27 +/- 21, 18 +/- 18, and 14 +/- 15 ms, respectively) but not at 300 ms (APD increase of 13 +/- 19 ms). Sematilide significantly prolonged the APD90 to a greater degree at longer than at shorter cycle lengths (P = .02). The ventricular effective refractory period had a similar reverse frequency-dependent relation as the APD90. Sematilide had no effect on the ventricular effective refractory period-to-APD90 ratio or on ventricular conduction. Sematilide suppressed the induction of sustained ventricular tachycardia in 41% of all patients exposed to sematilide. Prolongation of ventricular refractoriness was correlated with ventricular tachycardia suppression. The right ventricular effective refractory period (at 600 ms) increased by 38 +/- 14 ms in patients whose sustained ventricular tachycardia was suppressed by sematilide and by 19 +/- 18 ms in patients not suppressed (P = .015). One patient developed short runs of pause-dependent nonsustained ventricular tachycardia. Eight patients were placed on long-term sematilide therapy, and during a mean follow-up period of 7.0 +/- 7.5 months, two patients developed sudden cardiac death, and one additional patient had recurrent sustained ventricular tachycardia.

CONCLUSIONS

The electrophysiologic profile of sematilide is consistent with selective block of outward potassium currents and associated isolated lengthening of the ventricular effective refractory period and APD; sematilide demonstrates a significant degree of reverse frequency-dependence of the ventricular APD and effective refractory period; and suppression of ventricular tachycardia inducibility by sematilide appears to be correlated with increases in the right ventricular effective refractory period.

Noninvasive prediction of efficacy of type IA antiarrhythmic drugs by the signal-averaged electrocardiogram in patients with coronary artery disease and sustained ventricular tachycardia

This study attempted to determine if specific changes on the signal-averaged electrocardiogram (ECG) after type IA antiarrhythmic therapy are predictive of efficacy in the treatment of ventricular tachycardia (VT). Scalar and signal-averaged ECGs were obtained at baseline and after type IA drug therapy in 15 patients with coronary artery disease and inducible VT at baseline electrophysiologic testing. Signal-averaged QRS duration, root-mean-square amplitude in the last 40 ms of signal-averaged QRS, and the duration under 40 mu v of the signal-averaged QRS (low-amplitude signal), as well as ventricular effective refractory period at electrophysiologic study, and QTc on the scalar ECG were compared. At drug study, 6 patients (group A) had persistent but slower VT, whereas 9 (group B) had VT rendered noninducible. The baseline signal-averaged QRS duration was longer in group A than in B (136 +/- 10 vs 115 +/- 13 ms; p < 0.05), as was the scalar QRS (115 +/- 19 vs 98 +/- 11 ms; p < 0.05). After antiarrhythmic therapy, group A had a greater prolongation of both signal-averaged QRS (24 +/- 10 vs 8 +/- 3 ms; p < 0.05) and low-amplitude signal (31 +/- 13 vs 3 +/- 7 ms; p < 0.05), whereas group B had a greater increase in ventricular effective refractory period (49 +/- 20 vs 20 +/- 13 ms; p < 0.05) and corrected QT interval (100 +/- 39 vs 43 +/- 23 ms; p < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Sotalol and type IA drugs in combination prevent recurrence of sustained ventricular tachycardia

OBJECTIVES

This study assessed the efficacy of the combination of sotalol and either quinidine or procainamide in preventing sustained ventricular tachycardia inducibility and recurrence and prospectively evaluated the ability of the drug combination to prevent ventricular tachycardia recurrence when the arrhythmia remained inducible but was modified.

BACKGROUND

Individual antiarrhythmic drugs are often ineffective in preventing the induction and recurrence of sustained ventricular tachycardia. Beta-adrenergic blockade and prolongation of refractoriness may be important components of successful antiarrhythmic therapy in patients with ventricular tachycardia. We reasoned that the combination of sotalol, which has beta-adrenergic blocking properties and prolonged ventricular refractoriness, and quinidine or procainamide, two agents that slow conduction and prolong refractory periods, would be effective therapy in such patients.

METHODS

We administered low dose sotalol (205 +/- 84 mg/day) plus quinidine sulfate (1,278 +/- 479 mg/day) or procainamide (2,393 +/- 1,423 mg/day) to 50 patients with spontaneous sustained ventricular tachycardia or fibrillation and inducible ventricular tachycardia.

RESULTS

In 21 (46%) of 46 patients, ventricular tachycardia was rendered noninducible at electrophysiologic study (group I), and in 17 patients (37%), inducible tachycardia was modified according to prospectively identified criteria (group II), for a combined 83% response rate. Ventricular refractory periods increased from 252 +/- 24 to 316 +/- 28 ms and from 265 +/- 33 to 316 +/- 24 ms in groups I and II, respectively (p < 0.001), but from 234 +/- 19 to only 286 +/- 13 ms in the group of patients with unmodified ventricular tachycardia inducibility (n = 8, group III, p < 0.001). Cycle length of induced ventricular tachycardia slowed from 324 +/- 62 to 432 +/- 70 ms in group II patients (p < 0.001), whereas it slowed less in group III patients (279 +/- 73 to 314 +/- 63 ms, p = NS). Forty-two of the 50 patients (including all patients in groups I and II) were discharged on treatment with the drug combination. After 25 +/- 19 months of follow-up, the actuarial recurrence rate of ventricular tachycardia was 6%, 6% and 11% at 1, 2 and 3 years, respectively. Among patients in whom this drug combination was unsuccessful at electrophysiologic study (group III) and in those who received alternative therapy after combination therapy was discontinued because of side effects, actuarial recurrence rates were 9%, 14% and 32% at 1, 2 and 3 years, respectively.

CONCLUSIONS

The combination of sotalol plus quinidine or procainamide markedly prolongs ventricular refractoriness and slows induced ventricular tachycardia in a high proportion of patients. Patients with modified or noninducible tachycardia have a low rate of arrhythmia recurrence in follow-up. This drug combination deserves further evaluation.

Infarct artery patency predicts outcome of serial electropharmacological studies in patients with malignant ventricular tachyarrhythmias

BACKGROUND

Surviving myocardial cells near the infarct border zone form the arrhythmogenic substrate for sustained ventricular tachycardia (VT) in humans. Infarct-related artery (IRA) patency may modulate the electrophysiological function of this arrhythmogenic substrate and its response to antiarrhythmic drug therapy. We postulated that effective antiarrhythmic drug therapy selected during serial electrophysiological studies in patients with VT after a myocardial infarction would be identified more frequently when the IRA is patent than when chronically occluded.

METHODS AND RESULTS

Consecutive patients (n = 64) with documented coronary artery disease and remote myocardial infarction presenting with spontaneous sustained VT or ventricular fibrillation (VF) were studied. These patients underwent 4 +/- 2 electropharmacological studies identifying effective antiarrhythmic drug therapy in 16 (25%) patients. Drug responders did not differ significantly from nonresponders in demographic, electrocardiographic, angiographic, or hemodynamic measurements. A patent IRA was associated with antiarrhythmic drug response significantly more frequently than was an occluded IRA (45% versus 9%, p = 0.001). Patency of the IRA was the only independent predictor of response to antiarrhythmic drug therapy in this study population. The sensitivity and specificity of using a patent IRA to predict successful drug testing were 81% and 67%, respectively.

CONCLUSIONS

The outcome of electropharmacological studies was predicted by the patency of the IRA. A patent IRA was associated with a greater probability of finding effective drug therapy.

Drugs, surgery, cardioverter defibrillator: a decision based on the clinical problem

These three therapeutic options are the basis of sudden cardiac death prevention: antiarrhythmic drugs, surgery, and automatic implantable cardioverter defibrillator. Each of these treatments has specific favorable and unfavorable indications. Antiarrhythmic drugs are mainly limited by the low therapeutic profile, proarrhythmic effects, complex pharmacokinetics and pharmacodynamics, possible negative inotropic effects, and the possible change of the organic substratum. Arrhythmia surgery may be limited by the need of a highly trained center, by a relatively high perioperative mortality (up to 15%), and by limited electrophysiological and clinical indications. The implantable cardioverter defibrillator is an expensive tool with a theoretically wide range of clinical indications, with already proven efficacy in converting ventricular fibrillation to sinus rhythm but with unproven efficacy on prolonging survival because of a lack of controlled trials (which, we must admit, is also true for drugs and surgery). The results of the ongoing multicenter trials on this item will clarify this clinical point. The choice among these different therapeutic options is mainly based on hemodynamic status (ejection fraction), feasibility of a surgical treatment, and the electrophysiological characteristics of the ventricular arrhythmia.

Rate-dependence of class III actions in the heart

The pharmacodynamics of many antiarrhythmic drugs are altered by heart rate. The ability of sodium channel blockers to decrease conduction velocity (class I action) is more pronounced with rapid heart rates. Drugs with class III action increase action potential duration and refractoriness in the heart. Most drugs with class III actions, currently being developed, produce their action by blocking one or several of the potassium channels responsible for repolarization. In vitro and in vivo studies have shown that their ability to increase repolarization time is less pronounced, or even disappears, at rapid pacing or heart rates. This so called 'inverse' rate-dependence of class III action is a characteristic of all drugs currently used in man except amiodarone, for which prolongation of repolarization time persists to a limited extent with rapid heart rates. It has been suggested that one possible mechanism of the inverse rate-dependence of class III action is related to the preferential binding of drugs to the potassium channels in the closed, polarized state. An inverse rate-dependence of class III action has also been found on prolongation of refractoriness. However, preliminary studies suggest that the positive inotropism of class III drugs not only persists but may increase with rapid heart rates. The clinical consequences of this phenomenon remain unclear, especially in view of the fact that the rate-dependence of class III action on dispersion of repolarization has not been specifically studied and that class III actions tend to decrease in ischemic tissues. However, the increase of action prolongation at slow heart rates may contribute to the bradycardia-dependent development of torsades de pointes arrhythmias.(ABSTRACT TRUNCATED AT 250 WORDS)

Efficacy and electrophysiologic effects of oral sotalol in patients with sustained ventricular tachycardia caused by coronary artery disease

The efficacy of oral sotalol in preventing sustained ventricular tachycardia induction by invasive electrophysiological testing was assessed in 22 patients (60 +/- 9 years) with prior myocardial infarction. Programmed stimulation consisted of two basic drives followed by up to three extrastimuli at two right ventricular sites. At baseline, sustained monomorphic ventricular tachycardia was inducible in all patients. With sotalol (360 +/- 172 mg/day), it was no longer inducible in 10 patients; in 12 others, it remained inducible and its cycle length was only minimally prolonged (322 +/- 42 to 345 +/- 44 msec, p less than 0.05). Sotalol markedly prolonged sinus cycle length, uncorrected QT interval, and right ventricular effective and functional refractory periods, but had little effect on ventricular conduction time either in sinus rhythm or with right ventricular pacing. There was no significant difference in drug dose or in electrophysiologic effect of drug that related to efficacy, nor was there any correlation between drug-induced prolongation of ventricular tachycardia cycle length and its effects. Six patients received oral sotalol over the long term without spontaneous recurrence of ventricular tachycardia (follow-up: 23 +/- 18 months). These results demonstrate that sotalol is effective (45%) against sustained ventricular tachycardia induction at moderate doses and is well tolerated over a long term in the setting of remote myocardial infarction. However, its electrophysiologic effects as measured at invasive testing are not predictive of efficacy against ventricular tachycardia induction.