The effects of beta-adrenergic stimulation on the frequency-dependent electrophysiologic actions of amiodarone and sematilide in humans

The role of amiodarone in contemporary management of complex cardiac arrhythmias

Amiodarone is an iodinated benzofuran derivative, a highly lipophilic drug with unpredictable pharmacokinetics. Although originally classified as a class III agent due to its ability to prolong refractoriness in cardiac regions and prevent/terminate re-entry, amiodarone shows antiarrhythmic properties of all four antiarrhythmic drug classes. Amiodarone is a potent coronary and peripheral vasodilator and can be safely used in patients with left ventricular dysfunction after myocardial infarction or those with congestive heart failure or hypertrophic cardiomyopathy. Its use is regularly accompanied with QT and QTc-interval prolongation but rarely with ventricular proarrhythmia. It is the most powerful pharmacological agent for long-term sinus rhythm maintenance in patients with atrial fibrillation. Amiodarone, particularly if co-administered with beta-blockers, reduces the rate of arrhythmic death due to ventricular tachyarrhythmias in patients with heart failure, but its benefit on cardiovascular and overall survival in these patients is uncertain. In addition, amiodarone is an important adjuvant drug for the reduction of shocks in patients with an implantable cardioverter-defibrillator. Over the past 40 years, amiodarone became the most prescribed antiarrhythmic. Nevertheless, the slow onset of its antiarrhythmic action requires a loading dose while the high risk of non-cardiac toxicity and common drug-drug interactions limit its long-term use. Furthermore patients treated with amiodarone require a close supervision by the treating physician. Therefore amiodarone is generally considered a secondary therapeutic option. Long-term treatment with amiodarone should be based on the use of minimal doses for satisfactory arrhythmia outcome and serial screening for thyroid, liver and pulmonary toxicity.

Cross-trial comparisons: a source of confusion, use, or both in the management of patients with atrial fibrillation?

Many medical therapies are shaped by clinical trial data. However, individual clinical trial results sometimes appear discordant for the same tested treatments, and competing treatment strategies are often not directly tested. Clinicians are forced to make decisions by extrapolating information from different trials of similar but nonidentical therapies. In an era where increasing medical complexity demands sound evidence-based decisions, clinicians must navigate through these issues to arrive at optimal patient-specific management decisions. Using trials investigating therapies for atrial fibrillation, we attempt to highlight the important points for practitioners to consider when making these comparative intertrial judgments.

Effects of Dofetilide and EGIS-7229, an Antiarrhythmic Agent Possessing Class III, IV, and IB Activities, on Myocardial Refractoriness in Hyperkalemia, Hypokalemia, and During β-Adrenergic Activation in the Rabbit Papillary Muscle In Vitro

Lengthening of the effective refractory period (ERP) by EGIS-7229, a class III/Ib/IV drug, and by dofetilide, a selective I(Kr) blocker, was compared in normokalemia (NK), hypokalemia (LK), and hyperkalemia (HK) in right ventricular papillary muscles of rabbits paced at 0.5, 1, and 2 Hz, in vitro, and also during beta-adrenergic activation. In NK, EGIS-7229 (3 and 10 microM) and dofetilide (30 and 100 nM) similarly lengthened ERP in a steeply reverse frequency-dependent manner. The two compounds produced smaller ERP prolongations at 0.5 Hz in HK and LK, so rate-dependence of ERP changes decreased. EGIS-7229 lengthened ERP more at 2 Hz than at 0.5 Hz at 10 microM in LK, that is, the effect of EGIS-7229 turned into positive frequency-dependence from 3 to 10 microM. Furthermore, EGIS-7229 lengthened ERP at 10 microM more than dofetilide at 100 nM at 2 Hz stimulation rate (P<0.05). Isoproterenol (30 nM) eliminated the effect of dofetilide on ERP, while EGIS-7229 prolonged ERP during beta-adrenergic activation. In conclusion, efficacy of EGIS-7229 was superior to that of dofetilide in LK and during beta-adrenergic stimulation, suggesting improved antiarrhythmic action for EGIS-7229 under certain conditions in the patient.

The effects of sotalol on ventricular repolarization during exercise

OBJECTIVE

Although after pacing animal and human studies have demonstrated a rate-dependent effect of sotalol on ventricular repolarization, there is little information on the effects of sotalol on ventricular repolarization during exercise. This study attempted to show the effects of sotalol on ventricular repolarization during physiological exercise.

METHODS

Thirty-one healthy volunteers (18 males, 13 females) were enrolled in the study. Each performed a maximal treadmill exercise test according to the Bruce protocol after random treatment with sotalol, propranolol and placebo.

RESULTS

Sotalol significantly prolonged QTc (corrected QT) and JTc (corrected JT) intervals at rest compared with propranolol (QTc 324.86 ms vs 305.21 ms, P<0.001; JTc 245.04 ms vs 224.17 ms, P<0.001) and placebo (QTc 324.86 ms vs 314.06 ms, P<0.01; JTc 245.04 ms vs. 232.69 ms, P<0.001). The JTc percent reduction increased progressively with each stage of exercise and correlated positively with exercise heart rate (r=0.148, P<0.01). The JTc percent reduction correlation with exercise heart rate did not exist with either propranolol or placebo.

CONCLUSIONS

These results imply that with sotalol ventricular repolarization is progressively shortened after exercise. Thus the specific class III antiarrhythmic activity of sotalol, present as delay of ventricular repolarization, may be attenuated during exercise. Such findings may imply the need to consider other antiarrythmic therapy during periods of stress-induced tachycardia.

Open-State Unblock Characterizes Acute Inhibition of IKs Potassium Current by Amiodarone in Guinea Pig Ventricular Myocytes

INTRODUCTION

The aim of the present study was to investigate the acute action of amiodarone on the slow component of delayed rectifier K+ current (IKs) under basal conditions and during beta-adrenoceptor stimulation in guinea pig ventricular myocytes.

METHODS AND RESULTS

Using the whole-cell patch-clamp method, IKs was evoked by depolarizing voltage-clamp steps, during superfusion with the Na+-, K+-, and Ca2+-free solution supplemented with 0.4 microM nisoldipine and 5 microM E-4031. The acute effect of amiodarone was evaluated, within approximately 10 minutes after starting the bath application, by the amplitude of deactivating tail currents at -50 mV. Amiodarone concentration dependently blocked I(Ks) and exerted a more potent effect on IKs when activated by shorter pulse durations; the degree of block by 30 microM amiodarone on IKs activated by 200 ms, 500 ms, and 2000 ms depolarizing pulses to +30 mV was 55.9 +/- 5.8%, 38.6 +/- 6.0%, and 27.1 +/- 4.0% (n = 5 each), respectively. An envelope of tails test conducted at +10, +30, and +60 mV demonstrated that the degree of IKs block by amiodarone was gradually attenuated during membrane depolarization, which can be described by a monoexponential function, thus supporting the presence of open channel unblock. Amiodarone also blocked IKs maximally stimulated by 1 microM isoprenaline, to an extent similar to control, when IKs was activated by pulse durations of < or =2000 ms.

CONCLUSION

We propose that amiodarone acutely blocks native IKs with characteristics associated with open channel unblock, and that the protein kinase A-mediated phosphorylation of channel proteins only minimally affects the amiodarone block.

Ventricular fibrillation: new insights into mechanisms

Device therapy with implantable cardioverter-defibrillators is currently the only proven effective therapy against sudden cardiac death due to ventricular fibrillation. However, the expanded clinical indications for device therapy come at a staggering cost to an already overburdened health care system. Given these statistics, it is both highly desirable and economically imperative to develop alternative therapies. New insights into the mechanisms of ventricular fibrillation, particularly the role of dynamic factors causing wave instability, are providing a promising avenue for developing novel therapies to prevent sudden cardiac death.

Bepridil Block of Recombinant Human Cardiac IKs Current Shows a Time-Dependent Unblock

Whole-cell patch-clamp techniques were employed to examine the effects of bepridil, a Ca2+ channel blocker with Vaughan Williams class III action, on a slow component of cardiac delayed rectifier K+ current (IKs), which was reconstituted in HEK293 cells by transfecting KCNQ1 and KCNE1. Micromolar bepridil inhibited tail currents carried by KCNQ1/KCNE1 channels in a concentration-dependent manner (IC50 = 5.3 +/- 0.7 microM at -40 mV from 1000 milliseconds test pulse). When the effect of the drug was examined with a short test pulse protocol (250 milliseconds), IC50 became two-fold smaller than that measured with 1000 milliseconds test pulse (2.5 +/- 0.8 microM). The envelope-of-tails protocol was used to assess how the duration of depolarizing pulse affects the drug action on the outward KCNQ1/KCNE1 channel current. The drug significantly inhibited tail currents more potently during shorter pulses (<600 milliseconds). Bepridil's block was therefore time dependent, and its binding affinity to the channel was greater in the closed state channel, as evidenced by unblocking during prolonged depolarization. These properties of channel blockade appear to underscore the mechanism of bepridil's effect on IKs current.

Effects of isoproterenol and amiodarone on the double potential interval after ablation of the cavotricuspid isthmus

INTRODUCTION

A corridor of double potentials along the ablation line has been recognized to be an indicator of complete cavotricuspid isthmus block. Isoproterenol is used to confirm cavotricuspid isthmus block, but the effects of isoproterenol on the double potential interval (DPI), either in the absence or presence of amiodarone, are unknown.

METHODS AND RESULTS

Thirty-two patients with isthmus-dependent atrial flutter underwent successful ablation of the cavotricuspid isthmus. The procedure was performed in the drug-free state in 23 patients, and 2 to 7 days after discontinuation of chronic amiodarone therapy in 9 patients. Electrograms recorded along the ablation line before and during isoproterenol infusion were analyzed after isthmus block was achieved. Double potentials were recorded along the entire ablation line upon achievement of complete isthmus block in all patients. The DPI in 9 patients treated with amiodarone was longer than in the other patients (147 +/- 32 msec vs 119 +/- 19 msec, P < 0.001). The DPI increased as the pacing cycle length shortened in patients treated with amiodarone, but not in the other patients. At all pacing cycle lengths, isoproterenol shortened the DPI to a greater extent in the patients treated with amiodarone than in the other patients.

CONCLUSION

Amiodarone results in rate-dependent prolongation of the DPI during coronary sinus pacing after ablation of the cavotricuspid isthmus. Isoproterenol shortens the DPI despite the presence of complete isthmus block, and this effect is accentuated in the presence of amiodarone.

Beta-adrenoceptor activation plays a role in the reverse rate-dependency of effective refractory period lengthening by dofetilide in the guinea-pig atrium, in vitro

1. Blockers of the rapid component of the delayed rectifier potassium current (I(Kr)) prolong cardiac action potential duration (APD) and effective refractory period (ERP) in a reverse rate-dependent manner. Since activation of beta-adrenoceptors attenuates prolongation of APD evoked by I(Kr) blockers, rate-dependent neuronal noradrenaline liberation in the myocardium may contribute to the reverse rate-dependent nature of the effects of I(Kr) blockers. In order to test this hypothesis, we studied the effects of dofetilide, a pure I(Kr) blocker, on ERP after activation or blockade of beta-adrenoceptors and after catecholamine depletion in guinea-pig left atrial myocardium paced at 3, 2 and 1 Hz, in vitro. 2. Dofetilide (100 nM) lengthened ERP in a reverse rate-dependent manner in the left atrial myocardium of guinea-pigs. Strong activation of beta-adrenoceptors using 10 nM isoproterenol abolished the dofetilide-induced lengthening of ERP at all pacing rates. 3. Blockade of the beta-adrenoceptors with metoprolol (1 micro M), atenolol (3 micro M) or propranolol (300 nM) increased the dofetilide-evoked prolongation of ERP at 3 and 2 Hz, but not at 1 Hz. As a consequence, metoprolol attenuated while propranolol and atenolol fully eliminated the reverse rate-dependent nature of the dofetilide-induced ERP lengthening. In catecholamine-depleted atrial preparations of the guinea-pig (24 h pretreatment with 5 mg kg(-1) reserpine i.p.), the effect of dofetilide on ERP was not frequency dependent, and propranolol did not alter the effects of dofetilide. 4. In contrast to results obtained in guinea-pig atrial preparations, propranolol failed to change the reverse rate-dependent effect of dofetilide on ERP in the right ventricular papillary muscles of rabbits and guinea-pigs. 5. As an indication of the functional consequences of rate-dependent noradrenaline liberation, propranolol decreased twitch tension at 3 and 2 Hz but not at 1 Hz in the atrial myocardium of control guinea-pigs, whereas no such effect was detected in catecholamine-depleted atrial preparations. Propranolol failed to change contractility of ventricular myocardium in guinea-pigs and rabbits. 6. It is concluded that rate-dependent noradrenaline release and the ensuing beta-adrenoceptor activation contributed to the reverse rate-dependent nature of ERP prolongation caused by I(Kr) blockers in isolated guinea-pig atrial myocardium.

Antiarrhythmic drugs: new agents and evolving concepts

Properties of several new antiarrhythmic drugs are summarised in this review article. Recent concepts concerning their safety and efficacy of antiarrhythmics are discussed. A brief perspective on possible future strategies for pharmacotherapy of arrhythmias is provided.

Synthesis and activity of novel and selective I(Ks)-channel blockers

Since the discovery of the I(Ks)-potassium channel as the slowly activating component of the delayed rectifier current (I(k)) in cardiac tissue, the search for blockers of this current has been intense. During the screening of K(ATP)-channel openers of the chromanol type we found that chromanol 293B was able to block I(Ks). Chromanol 293B is a sulfonamide analogue of the K(ATP)-channel openers but had no activity on this target. Experiments were initiated to improve the activity and properties based on this lead compound. As a screening model we used Xenopus oocytes injected with human minK (KCNE1). Variations of the aromatic substituent and the sulfonamide group were prepared, and their activity was evaluated. We found that the greatest influence on activity was found in the aromatic substituents. The most active compounds were alkoxy substituted. We chose HMR1556 ((3R, 4S)-(+)-N-[-3-hydroxy-2,2-dimethyl-6-(4,4,4-trifluorobutoxy)chroman-4-yl]-N-methyl-ethanesulfonamide) 10a for development as an antiarrhythmic drug. The absolute configuration, resulting from an X-ray single-crystal structure analysis, was determined.

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.

Prolonged QT interval in acute psychotic patients

Some recent clinical studies indicate that hypokalemia is characteristic for acute psychotic patients at the time of emergency admission. As hypokalemia is one of the major causes for prolonged QT interval, it was hypothesized that acute psychotic patients could show prolonged QT interval. Sixty-seven drug-free, acute psychotic patients were evaluated for corrected QT (QTc) interval, as well as demographic and clinical characteristics at the time of emergency admission. The mean QTc interval of psychiatric emergency patients was prolonged, and the mean QTc interval of psychiatric emergency patients was longer than that of psychiatric outpatients (t=5.20, P<0.0001). Age- or gender-related difference, circadian fluctuation of QT interval, medication, concomitant disease, obesity, and serum electrolytes except potassium were not major causes. There was a significant negative correlation as evidenced by a coefficient of correlation of -0.28 (P<0.05). As psychiatric emergency patients often receive parenteral antipsychotics, which may have adverse effects on prolonged QT interval, paying attention to QT interval might have some clinical significance on emergency admission.

Salutary antiarrhythmic effect of combining a K channel blocker and a beta-blocker in a canine model of 7-day-old myocardial infarction

We sought to examine whether the antiarrhythmic effect of E4031 (E), or I(Kr) channel blocker, is affected by beta-adrenergic stimulation using isoproterenol (Iso) or by beta-adrenergic blockade (betaB) using, ONO1101, in a canine myocardial infarction model. Electrophysiologic studies were performed in 10 dogs with 7-day-old myocardial infarctions. Local QT intervals were measured at 47 sites on the infarcted myocardium using a mapping electrode. QT dispersion (QTd), as defined by the coefficient of variation of QT intervals, was obtained. Inducibility of ventricular arrhythmias was examined by programmed stimulation. These procedures were repeated during administration of E, E + Iso, and E + betaB. The effect of prolonging local QT intervals by E was counteracted by Iso, and was accentuated by betaB. The amount of prolongation was dependent on the baseline QT intervals, and QTd showed a tendency to decrease with E, to increase with E + Iso, and significantly decreased with E + betaB. Ventricular tachyarrhythmias were induced in a half of dogs with E + Iso, but were not induced with E + betaB. In the presence of adrenergic activation, I(Kr) blockers may exhibit a decreased antiarrhythmic effect. Beneficial synergism can be expected when an I(Kr) blocker is combined with a beta-blocker in the subacute phase of myocardial infarction.

Lessons from antiarrhythmic trials involving class III antiarrhythmic drugs

Beta-adrenergic blockers reduce mortality and sudden death in patients convalescing from myocardial infarction, and probably in patients with heart failure. However, the notion that class I antiarrhythmic drugs might save lives by suppressing the triggers of life-threatening ventricular arrhythmias was proved incorrect when the Cardiac Arrhythmia Suppression Trial (CAST) demonstrated that patients, whose ventricular ectopics were successfully suppressed by a number of class I antiarrhythmic drugs, died more readily than similar patients when treated with drugs rather than the placebo. Attention was diverted to class III antiarrhythmic drugs for patients with a poor ejection fraction who survived myocardial infarction and those with heart failure. A preliminary metaanalysis of 3 trials (Basel Antiarrhythmic Study of Infarct Survival [BASIS], Polish Amiodarone Trial [PAT], and the Canadian Amiodarone Myocardial Infarction Arrhythmia Trial [CAMIAT]) suggested that amiodarone might reduce arrhythmic and all-cause mortality in high-risk post-myocardial-infarction (MI) patients. BASIS suggested that this was only true for patients with preserved ventricular function. Nevertheless, 2 major trials were instituted: the European Myocardial Infarct Amiodarone Trial (EMIAT) and the CAMIAT. Both reported similar results except that patients recruited because of high-density ventricular ectopy seemed to benefit a little more from amiodarone than did patients with poor ventricular function. Detailed analysis of these trials revealed important insights into the value of amiodarone.

Sensitivity of the slow component of the delayed rectifier potassium current (IKs) to potassium channel blockers: implications for clinical reverse use-dependent effects

The slow delayed rectifier potassium current (I(Ks)) is unique in its slow activation and deactivation kinetics. It is important during cardiac repolarization, especially when the heart rate is fast. We compared the effects of quinidine, procainamide, sotalol, and amiodarone on I(Ks) and correlated the findings with the clinical reverse use-dependent effects of potassium channel blockers. Human minK RNA was obtained by reverse transcription-polymerase chain reaction using explanted human heart. The RNA was injected into Xenopus oocytes for heterologous expression of I(Ks). A two-electrode voltage clamp technique was performed to investigate the I(Ks). We demonstrated that quinidine, sotalol and procainamide had no effects on I(Ks) up to a concentration of 300 microM while amiodarone inhibited I(Ks) in a concentration-dependent manner starting from 10 microM. The inhibition by amiodarone was state-dependent with gradual unblocking after depolarization. The degree of inhibition was 53% immediately after depolarization and 19% at the end of a 5-second depolarization. I(Ks) is 30 times more sensitive to amiodarone than to quinidine, sotalol, and procainamide. Quinidine, sotalol and procainamide have reverse use-dependent effects while amiodarone does not. This is compatible with the hypothesis that no inhibition of I(Ks) at clinical concentrations contributes to the clinical reverse use-dependent effects.

Ambasilide prolongs the action potential and blocks multiple potassium currents in human atrium

Ambasilide (LU 47110) is a new class III antiarrhythmic drug with a unique profile of action in mammals; however, the effects on human atrial repolarization are not known. We tested the effects of ambasilide on action potentials and repolarizing potassium currents in single atrial myocytes. Ambasilide delayed all phases of repolarization in a concentration-dependent manner [i.e., 10 microM prolonged the action potential duration to 90% repolarization at 1 Hz from 217.8 +/- 34.1 to 360.6 +/- 63.0 ms (p < 0.05 vs. control)]. Action-potential prolongation was independent of the applied stimulation frequency over a range of 0.5-2 Hz; the drug therefore did not display reverse use dependence. Ambasilide produced a concentration-dependent block of the inward rectifier potassium current (IK1) and the acetylcholine-activated potassium current (IKACh) with a median effective concentration (EC50) of 6.0 and 2.3 microM, respectively. Ambasilide also led to a concentration-dependent inhibition of the transient outward current (Ito1; EC50 = 5.7 microM) and the sustained potassium outward current (ISO; EC50 = 43.6 microM). The effect of ambasilide was independent of the step voltage (in the range of +20 to +60 mV) or the applied stimulation frequency (0.5-2 Hz). Inactivation kinetics were not altered. Ambasilide is a new class III antiarrhythmic drug with a distinct profile of action. Its frequency-independent prolongation of the human atrial action potential makes this group of compounds a promising alternative to currently available class III antiarrhythmic drugs.

New advances in class III antiarrhythmic drug therapy

During the past 10 years there has been a major shift in antiarrhythmic drug development from class I to class III antiarrhythmic agents. The first two class III antiarrhythmic drugs that became available, sotalol and amiodarone, also have potent antiadrenergic actions. Newer antiarrhythmic drugs either block a specific ionic current (e.g., dofetilide-induced blockade of the rapidly activating component of the delayed rectifier potassium current) or block multiple ionic channels (e.g., ibutilide and azimilide) in order to prolong atrial and ventricular action potentials without other specific pharmacologic effects. Recent data suggest that these new class III antiarrhythmic drugs are highly effective for treating patients with rhythm disorders with an acceptable degree of proarrhythmia. This manuscript reviews the newer class III agents' effectiveness in treating atrial and ventricular arrhythmias and the recent studies examining drug-induced prolongation of atrial repolarization to prevent or terminate postoperative atrial fibrillation.

Modulation of antiarrhythmic drug effects by beta-adrenergic sympathetic stimulation

Appreciation has grown for the impact of the autonomic nervous system on the development of clinical cardiac arrhythmias. Antiarrhythmic medications work to significantly prolong cardiac repolarization and slow conduction. The question has arisen whether these pharmacologic actions of antiarrhythmic drugs can be modulated by alterations in the sympathetic nervous system. This article examines the data pertaining to modulation of the class I and class III effects of antiarrhythmic drugs during beta-adrenergic stimulation, the body's natural response to stress. The actions of several antiarrhythmic drugs can be fully reversed during beta-adrenergic sympathetic stimulation. Overall, the data suggest that pure class III drugs are the most susceptible to reversal of their effects on refractoriness, followed by class IA agents, amiodarone (which has partial resistance), and d,l-sotalol (which is highly resistant to reversal). Whereas retrospective analyses of a number of trials suggest that sympathetic-stimulation-induced reversal of the electrophysiologic effects of certain antiarrhythmic drugs can decrease their clinical efficacy, prospective trials examining this issue are needed. At the current time it appears reasonable to administer beta blockers to patients receiving antiarrhythmic agents that do not have intrinsic antiadrenergic effects.

MS-551 and KCB-328, two class III drugs aggravated adrenaline-induced arrhythmias

We investigated the proarrhythmic effects of MS-551 and KCB-328, class III antiarrhythmic drugs using adrenaline-induced arrhythmia models in halothane anaesthetized, closed-chest dogs. In the control period, adrenaline, starting from a low dose of 0.25 to up to 1.0 microg/kg/50 s i.v., was injected to determine the arrhythmia inducing dose and the non-inducing dose. After MS-551 or KCB-328 administration, the adrenaline injection was repeated and the interval between the injection and the occurrence of arrhythmia (latent interval), the changes in arrhythmic ratio (as calculated by dividing the number of ventricular premature contraction by the number of the total heart rate) and the severity of arrhythmia were observed. MS-551 infusion, 1 mg/kg/30 min, decreased the heart rate (HR) by 16% (P<0.01) and prolonged the QTc interval by 20% (P<0.01). During the 30 min of MS-551 infusion, arrhythmias occurred in three out of seven dogs (torsades de pointes (TdP) type VT in one dog). After these arrhythmias disappeared, MS-551 decreased the latent interval of the adrenaline arrhythmias produced by the inducing dose (30+/-2 s compared with 43+/-3 s of the control interval, P < 0.05), increased the arrhythmic ratio (P<0.05) and induced arrhythmias by non-inducing adrenaline doses (P<0.05). Effect of a new class III drug KCB-328 infusion, 0.3 mg/kg/30 min, was compared witih MS-551 using the same model. KCB-328 decreased the HR by 21% (P<0.01) and prolonged the QTc interval by 25% (P<0.01). During the 30 min of infusion, arrhythmias occurred in five out of seven dogs (TdP in two dogs). KCB-328 also decreased the latent interval of the adrenaline arrhythmias produced by the inducing doses (31+/-3 s compared with 49+/-7 s of the control period, P<0.05), but did not significantly alter the arrhythmic ratio. Adrenaline induced TdP only after MS-551 or KCB-328 was administered, i.e. after MS-551, 1 mg/kg/30 min, 3/7 versus 0/7 in the control; KCB, 0.3 mg/kg/30 min, 3/7 versus 0/7 in the control. To examine the direct arrhythmogenic effect of MS-551 and whether an adrenergic mechanism plays some role on this arrhythmogenesis, a bolus injection of MS-551, 3 mg/kg, was injected either without pre-treatment or after pre-treatment with propranolol 0.3 mg/kg. MS-551 induced arrhythmias in five out of seven dogs (TdP in one dog). Also in the propranolol pre-treated dogs, MS-551 induced arrhythmias in five out of seven dogs (TdP in 1 dog). In conclusion, these observations indicate that MS-551 and KCB-328 induced arrhythmias and intensified proarrhythmic effects of adrenaline, MS-551 being stronger than KCB-328 at the same QTc prolonging doses. The direct arrhythmogenic effect of MS-551 was not influenced by beta-blocker treatment.

Differential effect of beta-adrenergic stimulation on the frequency-dependent electrophysiologic actions of the new class III antiarrhythmics dofetilide, ambasilide, and chromanol 293B

INTRODUCTION

Blockade of the rapid delayed rectifier potassium current (IKr) as an important mechanism for current Class III antiarrhythmics is less effective in action potential prolongation during beta-adrenergic activation. We hypothesized that blockade of the increased slow IK (IKs) current during beta-adrenergic stimulation could improve action potential prolongation and tested this hypothesis by comparison of three different IK blockers: dofetilide, a selective blocker of IKr; ambasilide, a nonselective blocker of IK; and chromanol 293B, a selective blocker of IKs.

METHODS AND RESULTS

Transmembrane action potential duration was determined in guinea pig papillary muscles. After equilibration with the potassium channel blockers (dofetilide 10 nM, ambasilide 10 microM, chromanol 293B 10 microM), isoproterenol (10 and 100 nM) was added. The action potential prolonging effect of dofetilide was reduced in the presence of increasing concentrations of isoproterenol whereas the effect of ambasilide was much less reduced. In contrast, the effect of chromanol 293B clearly was increased in the presence of both concentrations of isoproterenol. No afterdepolarizations were observed after application of isoproterenol in control. Following isoproterenol, but not before, dofetilide and chromanol 293B induced early afterdepolarizations in 20% and 17% of the papillary muscles, whereas ambasilide and chromanol 293B induced delayed afterdepolarizations in 27% and 33%, respectively.

CONCLUSION

In contrast to dofetilide, the Class III effect of ambasilide is less reduced and the effect of chromanol 293B is enhanced during beta-adrenergic stimulation. Our data support the hypothesis that IKs blockade improves the efficacy of antiarrhythmics in action potential prolongation during beta-adrenergic activation; however, this effect may increase the risk of afterdepolarizations.

Changes in repolarization dynamicity and the assessment of the arrhythmic risk

At the present time, the assessment of the arrhythmic risk from surface ECG recordings is built on time-domain and frequent-domain analysis of high resolution ECG acquisition together with interlead variability of QT interval duration (QT dispersion). The corresponding raw ECG tracings are obtained in resting conditions. However, the dynamic aspects of the ECG signal is a rapidly evolving matter of interest. In addition to the beat-to-beat oscillations of the ventricular repolarization amplitude (QT alternans), there is growing evidence that the patterns of QT interval shortening with increasing heart rate are linked to susceptibility to ventricular arrhythmias. In this report, we will mainly address the association between QT dynamicity and the risk of developing torsades de pointes.

Regional entrainment of atrial fibrillation in man

INTRODUCTION

The feasibility of entrainment of macroreentrant atrial arrhythmias such as atrial flutter is well documented. Recently, it has been shown that regional entrainment of atrial fibrillation is feasible in dogs.

METHODS AND RESULTS

Three patients with chronic atrial fibrillation underwent electrophysiologic evaluation with attempted entrainment of atrial fibrillation prior to successful endocardial atrial defibrillation. A 16-pole catheter was positioned in the trabeculated right atrium, and in two patients a multipolar catheter was positioned along the septum. In addition, two large surface area defibrillation catheters were placed, one in the lateral right atrium and one in the coronary sinus. Regional entrainment was attempted in the right atrium and from the catheter in the coronary sinus. Entrainment was achieved in the right atrium in all three patients over a cycle length range of 28, 17, and 13 msec, respectively, and over a radius of atrial tissue of at least 2.8 cm. Regional entrainment was demonstrated from the coronary sinus in one patient during simultaneous right atrial entrainment. Termination of atrial fibrillation during entrainment was not observed.

CONCLUSION

Regional entrainment of chronic atrial fibrillation is feasible in humans.

Reverse use dependence of human ventricular repolarization by chronic oral sotalol in monophasic action potential recordings

Reverse use dependence of action potential duration and effective refractory period by chronic oral sotalol was demonstrated by monophasic action potential recordings in the human ventricle. There were no changes of the QRS duration over the cycle length, indicating that sotalol had no sodium channel blocking effects.

Frequency-dependent electrophysiologic effects of d,l-sotalol and quinidine and modulation by beta-adrenergic stimulation

INTRODUCTION

Frequency-dependent electrophysiologic actions of oral quinidine and oral sotalol may be clinically important, but these properties and their modulation by beta-adrenergic sympathetic stimulation have not been determined.

METHODS AND RESULTS

The frequency-dependent effects of oral quinidine (n = 17) and oral d,l-sotalol (n = 17) were determined at: (1) drug-free baseline; (2) during steady-state drug dosing; and (3) during isoproterenol infusion to patients receiving quinidine or d,l-sotalol. The monophasic APD90 and RVERP were prolonged 12% to 17% (P < 0.001) during pharmacologic therapy, and frequency-dependent effects were only observed for the RVERP during sotalol. In both drug groups, isoproterenol significantly reduced the sinus cycle length and reduced the RVERP to a greater extent at longer than at shorter paced cycle lengths. While isoproterenol fully reversed quinidine's effects on the APD90 and RVERP, sotalol-induced APD90 prolongation was reduced by only 2% to 4%, and the RVERP was unaffected. Isoproterenol attenuated the frequency-dependent effects of quinidine on QRS duration by a relatively fixed amount of 7% to 10%. Isoproterenol fully reversed quinidine-induced, but did not affect sotalol-induced prolongation in the sustained VT cycle length.

CONCLUSIONS

(1) Over the range of examined cycle lengths, oral quinidine and d,l-sotalol did not exert frequency-dependent effects on ventricular repolarization. (2) Isoproterenol fully reversed quinidine's effects on refractoriness, repolarization, and prolongation of VT cycle length, whereas d,l-sotalol's effects were largely preserved, despite significant reductions in sinus cycle length. (3) These results suggest that beta-blockade is important in preventing reversal of antiarrhythmic drug effects by augmented sympathetic nervous system tone.

Pharmacodynamic, pharmacokinetic and antiarrhythmic properties of d-sotalol, the dextro-isomer of sotalol

In recent years, there has been a major shift from the use of antiarrhythmic drugs that act by slowing conduction to those that exert their beneficial actions by lengthening cardiac repolarisation. Such a shift is occurring because sodium channel blockers may increase mortality, especially in patients with structural heart disease, and because drugs such as sotalol and amiodarone are effective, with a potential for decreasing arrhythmic mortality. In this context, the electrophysiological and antiarrhythmic properties of d-sotalol, the dextro-isomer of sotalol, are of major importance. d-Sotalol is essentially devoid of beta-blocking actions and may be considered a pure class III compound. It has been assumed that its clinical efficacy would approximate that of amiodarone and sotalol, but without the complex adverse effect profile of amiodarone and the adverse beta-blocker effects of racemic sotalol. d-Sotalol has pharmacokinetic properties that resemble those of the racemate. It lengthens the QT/QTc interval but does not affect other electrocardiographic (ECG) intervals. It increases the refractory period in the atria, ventricles, bypass tracts and the His-Purkinje system while minimally slowing the heart rate. In preliminary studies, it had a weak suppressant effect on premature ventricular contractions, prevented inducibility of ventricular tachycardia or fibrillation in about 40% of patients, and demonstrated the potential to terminate atrial flutter and fibrillation and maintain stability of sinus rhythm during prophylactic administration. The drug exhibits little or no negative inotropic actions. Thus, it is likely to be better tolerated in patients with congestive heart failure dependent on sympathetic stimulation for compensation. Because it produces less bradycardic effect than the racemate, it is believed that the drug might induce a lower rate of torsade de pointes. The role of d-sotalol in controlling cardiac arrhythmias is being addressed in a number controlled clinical trials. However, one such double-blind, placebo-controlled trial, Survival With Oral d-Sotalol (or SWORD), in survivors of myocardial infarction with depressed ventricular function was recently terminated prematurely because of a strikingly greater all-cause mortality compared with placebo (4.6 versus 2.6%). These preliminary findings, still to be fully analysed and interpreted for clinical significance, nevertheless raise valid concerns regarding the currently popular concept of controlling cardiac arrhythmias by the selective or isolated prolongation of repolarisation ('pure' class III action) as an antiarrhythmic principle.