Wolfgang Schöls

Inhibitory effects of the class III antiarrhythmic drug amiodarone on cloned HERG potassium channels.

The human ether-a-go-go-related gene (HERG) encodes a K+ channel with biophysical properties nearly identical to the rapid component of the cardiac-delayed rectifier K+ current (IKr). HERG channels are one primary target for the pharmacological management of arrhythmias. In this study, we investigated the acute effects of the class III antiarrhythmic drug amiodarone on HERG channels expressed heterologously in Xenopus oocytes by use of the two-microelectrode voltage clamp technique. Amiodarone blocked HERG channels with an IC50 of 9.8 µM with a maximum outward tail current reduction of 62.8%. The block consisted of two main components, a closed channel block that could not be reversed within the time of experiments and an open channel block with a slow unblock, having a recovery time constant of 73 s at –80 mV. Inactivation of the HERG channel at very positive potentials could not prevent amiodarone block. These results indicate that HERG channels can be blocked by amiodarone in closed, open and inactivated states. The block of open channels was cumulative, use-dependent and voltage-dependent. In summary, our data suggest that the strong class III antiarrhythmic action of amiodarone is at least partially based upon its acute inhibitory effects on HERG potassium channels.

The 1+1 trial: a prospective trial of a dual- versus a single-chamber implantable defibrillator in patients with slow ventricular tachycardias.

Background—The tachycardia detection interval (TDI) in implantable cardioverter/defibrillators (ICDs) is conventionally programmed according to the slowest documented ventricular tachycardia (VT), with a safety margin of 30 to 60 ms. With this margin, VTs above the TDI may occur. However, longer TDIs are associated with an increased risk of inappropriate therapy. We hypothesized that patients with slow VTs (<200 bpm) may benefit from a long TDI and a dual-chamber detection algorithm compared with a conventionally programmed single-chamber ICD. Methods and Results—Patients with VTs <200 bpm were implanted with a dual-chamber ICD that was randomly programmed to a dual-chamber algorithm and a TDI of ≥469 ms or to a single-chamber algorithm with a TDI 30 to 60 ms above the slowest documented VT cycle length and the enhancement criteria of cycle length variation and acceleration. The primary combined end point was the number of all inappropriate therapies, VTs above the TDI, and VTs with significant therapy delay (>2 minutes). After 6 months, a crossover analysis was performed. Total follow-up was 1 year. One hundred two patients were included in the study. The programmed TDI was 500±36 ms during the dual-chamber phase and 424±63 ms during the single-chamber phase. For the primary end point (inappropriate therapies, VTs above the TDI, or VTs with detection delay), a moderate superiority of the dual-chamber mode was found: Mann-Whitney estimator=0.6661; 95% CI, 0.5565 to 0.7758; P=0.0040. Conclusions—Dual-chamber detection with a longer TDI improves VT detection and does not increase the rate of inappropriate therapies despite a considerable increase in tachycardia burden.

Rate- and Site-Dependent Effects of Propafenone, Dofetilide, and the New IKs-Blocking Agent Chromanol 293b on Individual Muscle Layers of the Intact Canine Heart

BACKGROUND Recent in vitro studies have demonstrated regional differences in electrophysiological properties of individual left ventricular muscle layers. Controversy exists on the relevance of these findings for the situation in vivo. Thus, this study was designed to determine whether the in vivo canine heart exhibits regional differences in left ventricular refractoriness and in the susceptibility to sodium and potassium channel blockers. METHODS AND RESULTS In 16 dogs, 36 needle electrodes (12 mm long, 4 bipolar electrodes, interelectrode distance 2.5 mm) were inserted into the left ventricular wall. By use of a computerized multiplexer-mapping system, the spread of activation in epicardial, endocardial, and midmyocardial muscle was reconstructed during ventricular pacing at 300- and 850-ms basic cycle length (BCL). Effective refractory periods (ERPs) were determined at baseline and after application of propafenone (2 mg/kg), dofetilide (30 microg/kg), or chromanol 293b (10 mg/kg) by the extrastimulus technique (BCL 300 and 850 ms). At baseline, activation patterns and ERPs were uniform in all muscle layers. Propafenone homogeneously decreased conduction velocity and moderately prolonged ERPs without any regional differences. Dofetilide and chromanol 293b did not affect the spread of activation. Dofetilide exhibited reverse use-dependent effects on ERP, still preserving transmural homogeneity of refractoriness. Chromanol 293b led to a regionally uniform but more pronounced increase in local ERPs at faster than at slower pacing rates. CONCLUSIONS At the heart rates applied, the in vivo canine heart does not exhibit regional differences in electrophysiological properties. Given the homogeneity of antiarrhythmic drug effects, induction of local gradients of refractoriness is obviously not a common mechanism of proarrhythmia in normal hearts.

Incidence and Clinical Relevance of Slow Ventricular Tachycardia in Implantable Cardioverter-Defibrillator Recipients An International Multicenter Prospective Study

Background—This study aims to assess the incidence and clinical relevance of slow ventricular tachycardia (VT) and the effectiveness and/or deleterious effects of antitachycardia pacing in slow VT in implantable cardioverter-defibrillator recipients. Methods and Results—This multicenter prospective randomized study included 374 patients (326 men) without prior history of slow VT (<148 bpm) implanted with a dual-chamber implantable cardioverter-defibrillator. Patients had a 3-zone detection configuration: a slow VT zone (101 to 148 bpm), a conventional VT zone (>148 bpm), and a ventricular fibrillation zone. Patients were randomized to a treatment group (n=183) with therapy activated in the slow VT zone or a monitoring group (n=191) with no therapy in the slow VT zone. During follow-up (11 months), 449 slow VTs occurred in 114 patients (30.5% slow VT incidence); 181 VTs (54 patients) occurred in the monitoring group; 3 were readmitted to the hospital; and lightheadedness and palpitations occurred in 4 and 250 (60 patients) in the treatment group treated by antitachycardia pacing (89.8% success rate) and shock delivery (n=2). There were 10 crossovers from the monitoring to treatment group and 3 crossovers from the treatment to monitoring group (P=0.09). Quality of life scores were not different between groups. Conclusions—Slow VT incidence (<150 bpm) is high (30%) in implantable cardioverter-defibrillator recipients without prior history of slow VT, has limited clinical relevance, and is efficiently and safely terminated by antitachycardia pacing.

Electrophysiologic and antiarrhythmic effects of D-sotalol

There is extensive experimental and clinical experience concerning the antiarrhythmic potency of DL-sotalol, a β-adrenergic antagonist that lengthens the cardiac action potential duration. More recently, its dextrorotatory isomer, D-sotalol, has been evaluated in experimental studies and preliminary clinical trials. Whereas the isomer is almost free of β-blocking activity, both experimental and clinical data demonstrate the potent class III activity of D-sotalol. Further investigations, particularly in patients with life-threatening arrhythmias, are needed to delineate the clinical usefulness of this compound.

Isoproterenol specifically modulates reverse rate-dependent effects of d,l-sotalol, d-sotalol, and dofetilide.

The modulation of antiarrhythmic and proarrhythmic properties of antiarrhythmic compounds by increased sympathetic activity is of experimental and clinical interest. However, the interaction of adrenergic stimulation with the rate-response pattern of class III antiarrhythmic agents is not well established. Using standard microelectrode techniques, we evaluated the effects of isoproterenol (iso) on the action of d,l-sotalol (d,l-sot), d-sotalol (d-sot), and dofetilide (dof) on action-potential parameters recorded from isolated canine cardiomyocytes. The cell-isolation procedure was performed from the endocardial layers of left ventricular myocardium from healthy beagle dogs. The following electrophysiologic parameters were recorded: resting membrane potential (RMP), action-potential amplitude (APA), action-potential duration at 90% repolarization (APD 90), and effective refractory period (ERP). After exposure to iso, the class III activity of d,l-sot was well maintained over the entire range of frequencies studied. In contrast, iso differentially antagonized the action of d-sot and dof. In comparison to dof, the class III action of d-sot was particularly sensitive to iso, predominantly at faster stimulation rates. Our observations demonstrate specific rate regulation of the class III action of d,l-sot, d-sot, and dof in response to adrenergic stimulation. The unfavorable rate-response pattern of d-sot compared with d,l-sot and dof might prove disadvantageous in high-catecholamine states.

Differential effects of d-sotalol on subendocardial Purkinje myocytes isolated from normal or 10 to 14 days postinfarction canine hearts: role of extracellular potassium concentration.

Electrophysiologic properties of surviving Purkinje cardiomyocytes in the late postmyocardial-infarction phase are not well established. By using standard microelectrode techniques, we evaluated the effects of the class III agent d-sotalol on action potential parameters of single Purkinje cardiomyocytes isolated from normal canine hearts or those 10-14 days after infarction. Measurements were obtained at 2.5, 3.5, and 6 mM extracellular potassium concentrations. Action-potential parameters recorded at baseline did not differ significantly between normal and infarct-surviving Purkinje cardiomyocytes. At 3.5 and 6 mM extracellular potassium concentrations, surviving Purkinje cells appeared to be more sensitive to the effects of d-sotalol than normal Purkinje cells. In contrast, at 2.5 mM extracellular potassium concentration, the differential responses of normal and infarct-surviving Purkinje cells to d-sotalol was abolished. Reverse rate dependence was more prominent in normal than in postinfarction Purkinje cells, independent of the extracellular potassium concentration studied. The previously described enhanced sensitivity of subacutely infarcted tissue to class III agents seems to persist on a cellular level 10-14 days after myocardial infarction, even after full normalization of baseline action-potential parameters. Differential membrane-regulation mechanisms, dependent on the extracellular potassium concentrations, may account for the increased susceptibility to antiarrhythmia agents in the late postinfarction phase.

RATE AND TIME DEPENDENT EFFECTS OF D-SOTALOL ON THE MONOPHASIC ACTION POTENTIAL AFTER SUDDEN INCREASE OF THE HEART RATE

Experimental and clinical data suggests that almost all Class III antiarrhythmic agents diminish their ability to prolong cardiac repolarization at fast heart rates. However, only limited data exists about the time course of efficacy decay of Class III agents after sudden increase of the heart rate. In the present study, we assessed both rate and time dependent changes of the efficacy of d‐sotalol in higher stimulation frequencies following an abrupt increase in heart rate. This might imitate the situation seen in the development of paroxysmal tachycardias. Monophasic action potentials were recorded from the right ventricular apex during sinus rhythm and constant stimulation with the paced cycle length (PCL) of 550 ms, 400 ms, and 330 ms in the baseline and 20 minutes after intravenous administration of d‐sotalol (2.5 mg/kg) in seven patients with documented life‐threatening ventricular tachyarrhythmias. D‐sotalol significantly prolonged monophasic action potential duration at different steady‐state heart rates (sinus rhythm: 21.1%± 3.6%; PCL 550 ms: 16.6%± 4.3%, 400 ms: 11.2%± 2.7%, 330 ms: 5.8%± 2.1%). The prolongation is significantly shorter in higher steady‐state pacing, confirming a pronounced reverse‐use dependent decrease of the efficacy of d‐sotalol at faster stimulation frequencies. After the abrupt increase in heart rate, the beat‐to‐beat adaptation of the postdrug action potential prolongation exhibits only slight reverse‐use dependent shortening. The decrease of the efficacy of d‐sotalol is insignificant for the first 20 consecutive beats at the stimulation frequency of the PCL of 400 msec (from 16.6% at PCL of 550 ms to 14.6% at the 20th beat of the PCL of 400 ms), and for the first ten consecutive beats at the stimulation frequency of the PCL of 330 ms (from 16.8% at PCL of 550 ms to 12.3% at the 10th beat of the PCL of 330 ms). This slow decay of action potential prolongation after an abrupt increase in heart rate might contribute to the antiarrhythmic action of d‐sotalol in cardiac tachyarrhythmias.

Die Transmurale ERP-Dispersion von Epi-,Mid-und Endomyokard im gesunden und hypertrophierten Hundemyokard

ZusammenfassungViele Studien haben das Vorliegen von M-Zellen im Midmyokard des Hundes in vitro beobachtet und weiterhin gefunden, daß das Vorliegen von M-Zellen zur Differenz der Repolarisation und zur Dispersion der Refraktärzeit zwischen Midmyokard und Epi- und Endomyokard führen kann. Diese Dispersion hat enge Beziehungen mit der Entstehung der Arrhythmie. Aber die Beobachtungen in vitro waren nicht konkordant mit den Ergebnissen in vivo. Mittels direkten Messungen der ERP in drei Myokardschichten wurde erstmals im gesunden Hundemyokard und im hypertrophierten Hundemyokard in vivo untersucht. Die Untersuchung hat gezeigt. daß die ERP von Endomyokard, Epimyokard und Midmyokard im gesunden Hundeherzen homogen sind. Die relevante transmurale Refraktärgradient, die die Induktion einer kreisenden Erregung begünstigt, besteht unter physiologischen Bedingungen nicht. Im Gegensatz dazu konnte eine deutliche Verlängerung der ERP in allen Myokardschichten von hypertrophierten Hundeherzen nachgewiesen werden. Weiterhin wurde gezeigt, daß eine transmurale ERP-Dispersion zwischen verschiedenen Myokardschichten im hypertrophierten Hundemyokard besteht. Es ist zu postulieren, daß diese transmurale ERP-Dispersion als Substrat für die Arrhythmie angesehen werden kann, weil diese Dispersion die lokalen kreisende Erregung zwischen Epikard und Midkard, oder zwischen Midkard und Endokard begünstigen kann. Nach den Ergebnissen läßt sich postulieren, daß eine transmurale ERP-Dispersion durch eine plötzliche Zykluslängeveränderung, nämlich durch eine Kurz-Lang- und eine Lang-Kurz-Sequenz verstärkt werden kann.