Extracellular potassium modulation of drug block of IKr. Implications for torsade de pointes and reverse use-dependence

BACKGROUND

Torsade de pointes often occurs with underlying hypokalemia and bradycardia. A common effect of many drugs producing torsade de pointes is block of the rapidly activating component of the cardiac delayed rectifier (IKr). In this study, we evaluated the effect of changing extracellular potassium ([K+]o) on IKr block by the nonspecific agent quinidine and by the specific IKr blocker dofetilide.

METHODS AND RESULTS

IKr was measured in AT-1 cells, where contaminating outward currents are absent. The drug concentration producing 50% inhibition of IKr tails (IC50) was strikingly [K+]o-dependent. Elevating [K+]o from 1 to 8 mmol/L increased the IC50 for dofetilide block from 2.7 +/- 0.9 to 79 +/- 32 nmol/L and for quinidine block from 0.4 +/- 0.1 to 3.8 +/- 1.2 mumol/L.

CONCLUSIONS

(1) The increase in drug block with low [K+]o provides a mechanism to explain the link between hypokalemia and torsade de pointes. (2) Elevations in [K+]o occur with myocardial ischemia and with rapid pacing. Possible consequences of blunted drug block with high [K+]o include loss of drug efficacy with ischemia and with rapid pacing; the latter may contribute to "reverse use-dependent" action potential prolongation. Extracellular potassium is a critical determinant of drug block of IKr, with substantial clinical implications.

Anti-minK antisense decreases the amplitude of the rapidly activating cardiac delayed rectifier K+ current

The rapidly and slowly activating delayed rectifier K+ currents (IKr and IKs, respectively), which have different physiological properties have been identified in cardiac cells from several species, including humans. Although expression of the minimal K+ channel protein (minK) cDNA in some systems results in a current resembling IKs, the role of this gene product in channel function remains controversial. In atrial tumor myocytes (AT-1 cells), no IKs is recorded, but minK mRNA is detected, raising the possibility that expression of the minK gene serves an as-yet-unidentified function. In these experiments, AT-1 cells were exposed to antisense oligonucleotides targeting the 5' translation start site of the minK cDNA cloned from an AT-1 library. Cell size, IKr, and L-type and T-type Ca2+ currents were measured 24 to 48 hours after exposure and compared with data in cells exposed to the corresponding sense oligonucleotide or grown in medium only. Antisense oligonucleotide significantly reduced IKr compared with sense and medium-only control cells in 0 of 2 experiments (n = 3 to 6 cells per treatment in each experiment) at 50 nmol/L, 1 of 2 at 250 nmol/L, 6 of 6 at 1000 nmol/L, and 2 of 2 at 10,000 nmol/L. At 1000 nmol/L, maximum tail current in antisense-exposed cells was 2.5 +/- 0.1 pA/pF (mean +/- SEM, n = 28, 6 separate experiment), 6.6 +/- 0.4 pA/pF in sense-exposed cells (n = 27), 5.4 +/- 0.6 pA/pF in medium-only cells (n = 21), and 5.8 +/- 0.7 pA/pF in cells exposed to a random oligonucleotide (n = 9).(ABSTRACT TRUNCATED AT 250 WORDS)

Recent advances in understanding the molecular mechanisms of the long QT syndrome

Competing theories to explain the congenital long QT syndrome have included an imbalance in sympathetic innervation of the heart or a defect in repolarizing ion currents. Recent studies have identified at least four chromosomal loci at which mutations cause the congenital long QT syndrome in different families. The specific genes mutated in affected individuals have been identified at two of these loci, and both encode cardiac ion channels. The affected genes are SCN5A, the cardiac sodium channel gene, and HERG, whose protein product likely underlies IKr, the rapidly activating delayed rectifier. Thus, currently available evidence indicates that the congenital long QT syndrome is a primary disease of cardiac ion channels. Abnormalities in either inward or outward currents can cause the disease. Ongoing studies are evaluating the function of the mutant ion channels and the relationship between individual mutations and the clinical manifestations of the syndrome.

A randomized, double-blind, placebo-controlled, dose-ranging study of dofetilide in patients with inducible sustained ventricular tachyarrhythmias

INTRODUCTION

Dofetilide is a new antiarrhythmic agent with potent IK blocking properties in vitro. We developed a dose-ranging, placebo-controlled study design to define the range of effective doses and to evaluate the clinical electrophysiology of intravenous dofetilide in patients in whom sustained ventricular tachycardia or fibrillation was reproducibly inducible at baseline electrophysiologic testing.

METHODS AND RESULTS

The initial four patients received low doses that were increased in subsequent groups of four if adverse effects were absent. In each group of four patients, one patient was randomly assigned to placebo (double blind). Twenty-four patients were studied at six incremental loading and maintenance infusion regimens. Dofetilide (0.1 to 8.0 ng/mL) produced concentration-related increases in the % delta of QT (r = 0.79, P < 0.001), QTc (r = 0.60, P = 0.02), RR (r = 0.62, P < 0.02), and right ventricular effective refractory period (cycle length 600 msec; r = 0.68, P = 0.04). Placebo produced no changes in any of these measurements. Sustained ventricular tachycardia or ventricular fibrillation was no longer inducible in 1 of 6 patients receiving placebo and 8 of 18 receiving dofetilide (4 to 13 sec nonsustained ventricular tachycardia was induced in 4 of these 8). One patient developed torsades de pointes at a high concentration (5.3 ng/mL).

CONCLUSIONS

We conclude that: (1) dofetilide produces concentration-related IK blocking effects in patients; (2) an incremental dose-ranging study design aids in identifying the range of doses demonstrating electrophysiologic effects and efficacy; (3) a concomitant placebo group provides important data to assess reproducibility of results over time; and (4) further studies of dofetilide's efficacy and toxicity should be conducted.

Mechanism of block of a human cardiac potassium channel by terfenadine racemate and enantiomers

1. The cardiac toxicity of racemic terfenadine (marked QT prolongation and polymorphic ventricular arrhythmias) is probably due to potassium channel blockade. To test whether one of its enantiomers would be a less efficient potassium channel blocker, we compared the mechanism of action of the racemate with that of the individual enantiomers. 2. We synthesized the individual enantiomers of terfenadine and examined under whole cell voltage-clamp conditions the mechanism of action of the racemate, both enantiomers and a major metabolite on a cloned human cardiac potassium channel, hKv1.5. This delayed rectifier is sensitive to quinidine, clofilium and other 'class III' antiarrhythmic drugs at clinically relevant concentrations. 3. Upon depolarization, racemic terfenadine and its enantiomers induced a fast decline of hKv1.5 current towards a reduced steady state current level. During subsequent repolarization the tail currents deactivated more slowly than the control, resulting in a 'crossover' phenomenon. 4. The voltage-dependence of block was biphasic with a steep increase in block over the voltage range of channel opening (-30 to 0 mV), and a more shallow phase positive to 0 mV (where the channel is fully open). The latter was consistent with a binding reaction sensing 21% of the transmembrane electrical field (with reference to the cell interior). 5. The EC50 for hKv1.5 block by racemic terfenadine was 0.88 microM, while the values for R- and S-terfenadine were 1.19 microM and 1.16 microM, respectively. In contrast, the acid metabolite reduced hKv1.5 current by only 5% at a concentration of 50 microM. 6. These findings suggest that terfenadine blocks the hKvl.5 channel after it opens by entering into the internal mouth of the channel. We have previously shown that quinidine blocks hKvl.5 in a similar manner but with an apparent affinity of ~6 micro M. Thus, terfenadine and its enantiomers are approximately equipotent open state blockers of this human K+ channel and about 6 times more potent than quinidine. The similar state-, time-, and voltage-dependence of hKvl.5 block by both enantiomers also indicates that the chiral centre does not significantly constrain the orientation of critical binding determinants of terfenadine with respect to the receptor site.

Ibutilide, a methanesulfonanilide antiarrhythmic, is a potent blocker of the rapidly activating delayed rectifier K+ current (IKr) in AT-1 cells. Concentration-, time-, voltage-, and use-dependent effects

BACKGROUND

Ibutilide is an action potential-prolonging antiarrhythmic currently in clinical trials. The drug shares structural similarities with E-4031 and dofetilide, specific blockers of the rapidly activating delayed rectifier K+ current (IKr). However, previous in vitro studies in guinea pig myocytes have indicated that ibutilide does not block IKr but rather increases a slow inward sodium current.

METHODS AND RESULTS

In this study, we compared the effects of ibutilide with those of dofetilide on outward current in mouse atrial tumor myocytes (AT-1 cells), a preparation in which, unlike guinea pig, a typical IKr is the major delayed rectifier and can be readily recorded in isolation from other currents. In AT-1 cells, ibutilide and dofetilide were both potent IKr blockers, with EC50 values of 20 (n = 12) and 12 (n = 8) nmol/L, respectively, at +20 mV. The time and voltage dependence of IKr inhibition by the two compounds were virtually identical. The following characteristics were most consistent with open channel block: (1) block increased with depolarizing pulses; (2) block increased with longer pulses; (3) currents deactivated more slowly in the presence of drug, resulting in a "crossover" typical of open channel block; and (4) with repetitive pulsing after drug wash-in, use-dependent block was observed.

CONCLUSIONS

These data suggest that the clinical actions of ibutilide are mediated at least in part by block of IKr; an effect on inward currents is not excluded. AT-1 cells are a useful model system for the study of drug block of this important repolarizing current.

K+ currents and K+ channel mRNA in cultured atrial cardiac myocytes (AT-1 cells)

Atrial tumor myocytes derived from transgenic mice (AT-1 cells) maintain a well-differentiated cardiac biochemical and histological phenotype. In addition, they beat spontaneously in culture and exhibit long action potentials whose repolarization resembles that observed in native mammalian myocytes. In this study, we identified the major depolarization-activated outward currents in AT-1 cells; also, the presence of mRNAs that encode outwardly conducting ion channels was determined by cloning from an AT-1 cDNA library or by Northern hybridization. Among K+ channel isoforms, Kv2.1, minK, and Kv1.4 were readily detected in tumors and at 1 day in culture. Their abundance remained relatively stable (twofold or less change) after 14 days. The major outward current in AT-1 cells is a delayed rectifier that displays prominent inward rectification, activates rapidly (eg, 182 +/- 27 milliseconds [mean +/- SEM] at + 20 mV, n = 12), exhibits biexponential deactivation kinetics, and is extremely sensitive to the methanesulfonanilide dofetilide (IC50, 12 nmol/L). These characteristics identify this current as IKr, a delayed rectifier observed only in cardiac cells. IKr in AT-1 cells displayed slow inactivation: dofetilide-sensitive deactivating tails were greater after 1-second than after 5-second pulses. When IKr was blocked by > or = 0.5 mumol/L dofetilide, time-independent current was usually recorded (50 of 65 experiments); rapidly inactivating (6 of 65) or slowly inactivating (9 of 65) outward currents were occasionally observed. We conclude that AT-1 cells express mRNAs encoding cardiac K+ channels and display a cardiac electrophysiological phenotype.(ABSTRACT TRUNCATED AT 250 WORDS)

Block of IKs, the slow component of the delayed rectifier K+ current, by the diuretic agent indapamide in guinea pig myocytes

There is a high incidence of diuretic use among patients who develop exaggerated QT prolongation and polymorphic ventricular tachycardia (torsade de pointes) during treatment with action potential-prolonging agents. Diuretic-induced hypokalemia is thought to be the usual mechanism, but a direct effect of diuretic drugs on repolarizing currents is an additional possibility. Therefore, in this study, we examined the effects of the diuretic agents chlorthalidone and indapamide on the cardiac delayed rectifier current. In guinea pig ventricular myocytes, this current is made up of two components: IKr, a rapidly activating, inwardly rectifying current blocked by most action potential-prolonging antiarrhythmics, and IKs, a slowly activating component. In this preparation, indapamide blocked outward current in a time-, voltage- and concentration-dependent fashion, whereas chlorthalidone (1 mmol/L) was without effect. The following features of the effect of indapamide strongly suggest selective block of IKs: (1) Indapamide block was significantly greater with 5000-millisecond activating pulses (-43 +/- 5% at +50 mV [100 mumol/L indapamide]) than with 225-millisecond ones (-20 +/- 5%; n = 5, P < .01), and the signature of the indapamide-sensitive current was a slowly activating delayed rectifier current. (2) The voltage dependence of indapamide block (EC50, 101 mumol/L at +50 mV and 196 mumol/L at +10 mV) was consistent with preferential block of IKs relative to IKr. (3) In the presence of indapamide, an envelope-of-tails test for IKr was satisfied. The drug-insensitive current had rectifying properties similar to those described for IKr in these cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of procainamide and lidocaine on defibrillation energy requirements in patients receiving implantable cardioverter defibrillator devices

INTRODUCTION

In acute canine studies, lidocaine, but not procainamide, increases defibrillation energy requirements. We evaluated the effects of lidocaine or procainamide on defibrillation energy requirements in 27 patients undergoing intraoperative testing for implantable cardioverter defibrillator device placement.

METHODS AND RESULTS

Patients were tested off antiarrhythmic drugs and again following either lidocaine (200 to 250 mg loading and 3 mg/min maintenance infusions) or procainamide (1 gm loading and 3 to 4 mg/min maintenance infusions). The defibrillation testing protocol consisted of initial testing at 15 J, followed by higher or lower energies to determine the lowest energy producing three consecutive successful defibrillations. Overall, the mean defibrillation energy increased from 14 +/- 5 J to 18 +/- 7 J during lidocaine (plasma concentration 5.1 +/- 1.6 micrograms/mL; P < 0.02) but were similar at baseline (12 +/- 5 J) and during procainamide infusion (13 +/- 6 J) (plasma concentration: procainamide 10.7 +/- 7.2 micrograms/mL; N-acetyl procainamide 1.0 +/- 0.4 micrograms/mL). A positive linear correlation was found between lidocaine plasma concentration and percent change in defibrillation energy (lidocaine: r = 0.61; P = 0.01). Procainamide raised the defibrillation energy in three patients, two with supratherapeutic plasma concentrations. The increase in defibrillation energy equaled or exceeded 25 J in four patients after lidocaine and in one patient after procainamide.

CONCLUSION

The data suggest that at high plasma concentrations, lidocaine and procainamide adversely affect defibrillation energy requirements consistent with an adverse, concentration-dependent effect of sodium channel blockade on defibrillation energy requirements in patients.

Effect of hypercapnic acidemia on anisotropic propagation in the canine ventricle

BACKGROUND

Impulse propagation in the ventricle depends on both sodium channel availability and cell-to-cell coupling through gap junctions. Sodium channel block has been shown to depress conduction velocity (theta) more longitudinal (LONG) to than transverse (TRANS) to fiber orientation. Because exposure to CO2 produces intracellular acidosis and decreased gap junction conductance in vitro, we tested the hypothesis that increased PCO2 would result in preferential depression of transverse conduction in vivo.

METHODS AND RESULTS

In anesthetized dogs, when atrial pH was reduced to 6.70 +/- 0.04 by increasing the fraction of inhaled CO2 to 40%, theta TRANS fell from 0.23 +/- 0.04 to 0.19 +/- 0.02 m/s (-16 +/- 8%, P < .03), while theta LONG was unchanged (-3 +/- 7%, P = NS). In contrast, with the same degree of acidemia produced by HCl infusion, only theta LONG fell (-8 +/- 7%), coincident with a rise in serum K+.

CONCLUSIONS

The observed effect of CO2 on propagation in the intact heart is consistent with its previously described in vitro actions to uncouple cell-to-cell communication and may provide a model to study the role of cell-to-cell coupling in normal and abnormal propagation.

Quinidine-enhanced beta-blockade during treatment with propafenone in extensive metabolizer human subjects

Propafenone, a sodium channel blocking antiarrhythmic drug with beta-blocking properties, is metabolized to non-beta-blocking metabolites in part by cytochrome P4502D6. Subtherapeutic doses of quinidine inhibit P4502D6 and increase plasma propafenone in extensive metabolizer subjects, in whom the active enzyme is present. In this study we tested the hypothesis that quinidine would enhance beta-blockade in extensive metabolizers receiving propafenone. Seven extensive and two poor metabolizers received propafenone (225 mg orally every 8 hours) plus quinidine sulfate (60 mg orally every 8 hours) or propafenone plus placebo for 7 days in a randomized, double-blind, crossover fashion. In extensive metabolizers, the coadministration of quinidine significantly increased the extent of propafenone-induced beta-blockade, assessed by a decrease in exercise heart rate and by sensitivity to isoproterenol. We conclude that low-dose quinidine enhances propafenone-induced beta-blockade in extensive metabolizers. Thus the polymorphic patterns of drug metabolism can result in clinically significant drug interactions on a genetic basis.

Pharmacokinetics of amiodarone: implications for drug therapy

Amiodarone is a complex molecule with multiple pharmacologic properties and a complex electrophysiologic profile. Its disposition kinetics and relation between plasma drug concentration and efficacy can be analyzed using principles identical to those applicable to other antiarrhythmic drugs. However, the drug's affinity for lipophilic tissues, its extremely slow elimination rate, and the likelihood that some of its effects may not be mediated by the usual antiarrhythmic mechanisms confounds traditional pharmacokinetic analysis. Further data that deal with the fundamental mechanisms of action of the drug, in addition to the nature of the relation between dose and uptake into cellular and subcellular fractions and its pharmacologic effects, will be of value in understanding how the drug exerts salutary actions in cardiac arrhythmias.

Penetrating injuries to the neck: a safe, selective approach to management

The most appropriate management of patients with penetrating injuries to the neck remains a controversial issue. In order to determine the safety and efficacy of a selective approach to the management of such patients, a retrospective review of our experience with penetrating injuries to the neck at Northwestern Memorial Hospital over the past 5 years since the designation as a Level I trauma center was undertaken. A total of 30 patients fulfilled entry criteria. Twelve patients underwent immediate operative exploration based upon clinical indications present at admission. Seventeen patients underwent further diagnostic evaluation, including angiography in 17 and contrast esophagography in eight. Endoscopy was used infrequently. The mortality rate was 13.3 per cent, there were two negative cervical explorations, and there were no missed injuries. The results support the application of a selective approach to the operative management of penetrating injuries to the neck.

Early after-depolarizations and torsade de pointes: implications for the control of cardiac arrhythmias by prolonging repolarization

Common clinical features in drug-induced torsade de pointes include hypokalemia and cycle-length prolongation just prior to initiation of the arrhythmia. In canine Purkinje fibres, drugs known to be associated with torsade de pointes, such as quinidine, sotalol or N-acetylprocainamide, consistently produce early after-depolarizations (EADs) and triggered activity at slow drive rates; for quinidine, these abnormalities are exaggerated by low extracellular potassium. Triggered activity can be abolished in vitro in two ways. First, action-potential shortening with abolition of EADs can be accomplished by increasing stimulation rates, beta-stimulation and action-potential shortening antiarrhythmics such as lidocaine. Second, triggered activity can be suppressed, with less prominent effects on EADs, by magnesium, alpha- and/or beta-adrenergic blockade and calcium-channel blockers. The parallels between these in vitro findings and clinical torsade de pointes suggest that EADs and triggered activity play a role in the genesis of the clinical arrhythmia. Further research directed at determining the mechanisms underlying the cellular abnormalities and their propagation to the whole heart should yield information that will increase the safety of antiarrhythmic therapy.

Torsade de pointes

The polymorphic ventricular tachycardia torsade de pointes can occur in the congenital long QT syndromes or as a consequence of therapy with QT-prolonging drugs. The latter can include not only antiarrhythmic drugs such as quinidine, but also a number of drugs which are not usually considered to have major cardiovascular effects: these include nonsedating antihistamines, such as terfenadine; antibiotics such as erythromycin; and neuroleptics such as thioridazine. The electrocardiographic hallmark of both the congenital and acquired forms of the long QT syndrome is marked QT(U) lability, particularly as a function of heart rate. The underlying mechanism is thought to be triggered activity arising as a consequence of early afterdepolarizations. An understanding of the basic mechanism has led to an understanding of the effective forms of therapy, which include maneuvers to include the heart rate (pacing, isoproterenol) as well as maneuvers which may not necessarily alter the QT interval but may prevent the arrhythmia (magnesium, beta blockers). Intensive study of the clinical features and basic mechanisms underlying torsade de pointes has led to the definition of a new mechanism for cardiac arrhythmias; understanding such mechanisms may ultimately lead to the development of safer antiarrhythmic therapy.

Current status of class III antiarrhythmic drug therapy

Studies in animal models, as well as clinical experience with amiodarone and sotalol, suggest that action potential prolongation may be a useful antiarrhythmic mode of action. A number of agents that produce this class III effect are currently under development. The single greatest liability for further development of this group of drugs is the occasional, and apparently unpredictable, development of exaggerated QT prolongation and polymorphic ventricular tachycardia (torsades de pointes). Available data suggest that QT interval prolongation is not a good indicator of whether or not a class III antiarrhythmic will suppress a target arrhythmia; however, exaggerated QT prolongation is a predictor of torsades de pointes. Further studies to delineate the mechanism underlying the development of torsades de pointes might lead to safer and more effective antiarrhythmic drugs.

Usefulness of sotalol for life-threatening ventricular arrhythmias

Two trial designs have been used in evaluating sotalol in patients with sustained tachyarrhythmias: open-label dose escalation and randomized comparison with reference agents. At least 7 open-label studies (n = 16-65) have been reported from single centers in patients in whom trials of numerous other antiarrhythmic agents were unsuccessful. At the doses used, usually 320-640 mg/day, plasma concentrations were in the range associated with both beta blockade and class III antiarrhythmic activity (2-3 micrograms/mL). These concentrations produced electrophysiologic changes that were consistent across studies: 10-16% increase in right ventricular effective refractory period (ERP), 4-8% increase in corrected QT interval (QTc), and 17-30% increase in sinus cycle length (corresponding to a 15-23% decrease in heart rate). In these open-label trials, sotalol suppressed inducible ventricular tachyarrhythmias in 20-72% of patients; the higher degrees of efficacy were reported when induction protocols were confined to double extrastimuli. Side effects leading to discontinuation of sotalol in patients with sustained ventricular tachycardia or fibrillation include fatigue (4.0%), marked bradycardia (3.0%), torsades de pointes (3.0%), and heart failure or pulmonary edema (1.0%). A multicenter randomized trial compared intravenous sotalol with intravenous procainamide in a double-blind prospective fashion. Sotalol suppressed ventricular tachyarrhythmias inducible with triple extrastimuli in 15 (30%) of 50 patients, whereas procainamide was effective in 10 (20%) of 50. In this and other series, responsiveness to sotalol was prospectively identified by a particularly fast tachycardia at baseline (e.g., cycle length of < 270 msec), but not by the extent of changes in global indices of repolarization (QTc, ERP).(ABSTRACT TRUNCATED AT 250 WORDS)

Immediate- versus controlled-release disopyramide: importance of saturable binding

OBJECTIVE

To examine the effects of saturable plasma binding on the pharmacokinetics of immediate-release (IR) and controlled-release (CR) disopyramide.

BACKGROUND

Saturable binding causes a lack of correspondence between the pharmacokinetics of total and unbound plasma disopyramide. Levels of total drug may therefore be insensitive to important differences between formulations.

METHODS

Patients receiving long-term disopyramide underwent serial blood sampling during withdrawal of equivalent doses of IR and CR disopyramide, and during accumulation of IR disopyramide. Plasma disopyramide was measured by enzyme-multiplied immunoassay technique, protein binding by ultrafiltration, and alpha 1-acid glycoprotein by radial immunodiffusion. Pharmacologic effect was assessed by use of high-speed ECGs. Values for plasma area under the concentration-time curve and elimination half-life were determined from the log-plasma concentration data; rate of plasma drug accumulation was determined by nonlinear modeling.

RESULTS

Saturable plasma binding was evident in all patients. Comparison of total to unbound drug showed that peak-to-trough ratios during steady state were smaller (1.45 versus 2.39; p < 0.001), elimination half-life was longer (12.1 versus 4.5 hours; p < 0.001), and the time to achieve 50% of steady-state levels during drug accumulation was shorter (8.1 versus 4.3 hours; p < 0.05). Comparison of IR and CR disopyramide showed that unbound drug levels for CR disopyramide revealed lower peak plasma concentrations (0.75 versus 0.96 micrograms/ml) and peak-to-trough ratios (1.83 versus 2.31; p < 0.001). Trough plasma concentrations were similar. Fluctuations in ECG intervals during usual dosing were observed only with IR disopyramide.

CONCLUSIONS

Because of saturable plasma binding, total plasma concentrations underestimate fluctuations in unbound disopyramide during usual dosing and are insensitive to significant differences between IR and CR formulations. CR disopyramide provides less interdose variation in free drug levels and more constant pharmacologic effects.

Suppression of longitudinal versus transverse conduction by sodium channel block. Effects of sodium bolus

BACKGROUND

Arrhythmias resulting from treatment with sodium channel-blocking antiarrhythmic drugs have been successfully treated with sodium infusion, although the mechanism underlying this effect is uncertain.

METHODS AND RESULTS

In this study, we used a multielectrode array to examine the effects of O-desmethyl encainide (ODE), a potent sodium channel-blocking metabolite of encainide, on conduction in canine ventricle. ODE depressed both longitudinal and transverse conduction velocities in a plasma concentration-related fashion (r = -0.74, -0.60; p less than 0.001). At ODE concentrations less than or equal to 300 ng/ml (n = 34), conduction velocity was depressed to the same extent in the longitudinal (-21.9 +/- 8.4%, SD) and transverse orientations (-22.0 +/- 8.8%). However, at concentrations greater than 300 ng/ml (n = 17), conduction was significantly more impaired longitudinally than transversely (-44.5 +/- 11.7% versus -34.4 +/- 13.7%, p less than 0.02). In 12 animals with high concentrations (mean, 432 +/- 32 ng/ml), a 5-meq/kg bolus of sodium chloride over 1 minute immediately increased conduction velocity; this effect was significantly greater and longer lasting in the longitudinal orientation. In two animals, conduction block in the longitudinal orientation was documented at high plasma ODE and was immediately reversed by sodium bolus.

CONCLUSIONS

We conclude that the major effect of sodium in animals with excess sodium channel block is improvement of longitudinal propagation; this effect may underlie the antiarrhythmic action of sodium in the analogous clinical setting.

The Cardiac Arrhythmia Suppression Trial: first CAST ... then CAST-II

The Cardiac Arrhythmia Suppression Trial (CAST) was a study designed to test the hypothesis that suppression of ventricular premature complexes after a myocardial infarction would improve survival. Preliminary results showed that suppression of ventricular premature complexes with encainide and flecainide worsened survival, and the CAST continued as the CAST-II with moricizine compared with its placebo. The protocol for the CAST-II was changed to attempt to enroll patients more likely to experience serious arrhythmias. The enrollment time was narrowed to 4 to 90 days after myocardial infarction; the qualifying ejection fraction was lowered to less than or equal to 0.40; a higher dose of moricizine could be used; early titration itself was double-blind with a placebo, and the definition of disqualifying ventricular tachycardia was changed to allow patients with more serious arrhythmias to be entered into the trial. The Cardiac Arrhythmia Suppression Trial-II was subsequently terminated prematurely because 1) patients treated with moricizine had an excessive cardiac mortality rate during the 1st 2 weeks of exposure to the drug, and 2) there appeared to be little chance of showing a long-term survival benefit from treatment with moricizine. This report outlines the rationale behind the Cardiac Arrhythmia Suppression Trial and the reasons for selection of the drugs used in the CAST and CAST-II.

Stereoselective genetically-determined interaction between chronic flecainide and quinidine in patients with arrhythmias

1. Recent reports have indicated a role for the P450IID6 polymorphism in the stereoselective disposition of single doses of the antiarrhythmic flecainide. 2. In this study, we evaluated the effects of adding low dose quinidine, a potent inhibitor of P450IID6, to chronic flecainide therapy in patients with arrhythmias. 3. In five extensive metabolizer patients, quinidine significantly reduced the clearance of R-(-)-flecainide, from 395 +/- 121 (s.d.) to 335 +/- 88 ml min-1. This change was attributable to a decrease in metabolic clearance, was accompanied by decreased formation of the two major metabolites of flecainide and was not observed in a poor metabolizer subject. The renal clearance of R-(-)-flecainide rose significantly. 4. Quinidine did not alter the clearance of S-(+)-flecainide. 5. The pharmacologic effects of flecainide therapy (QRS widening, % arrhythmia suppression) were slightly, but not significantly, increased. 6. In extensive metabolizer patients receiving chronic flecainide, increased plasma concentrations will develop if P450IID6 is inhibited.

Pharmacology of the class III antiarrhythmic agent sematilide in patients with arrhythmias

Sematilide, a close structural analog of N-acetylprocainamide, prolongs cardiac action potentials in vitro, whereas it does not depress maximum action potential upstroke slope, a "class III" action. This report outlines an evaluation of the clinical pharmacologic actions of sematilide in 14 patients with chronic high-frequency nonsustained ventricular arrhythmias. In all, 36 intravenous infusions (range 0.15 to 1.5 mg/kg over 15 minutes) were administered in a dose-ranging, placebo-controlled study design. Sematilide prolonged rate-corrected QT (QTc) in a dose- and concentration-related fashion, did not alter PR or QRS, and slowed heart rate at high concentrations (greater than or equal to 2 micrograms/ml). The relations between dose and total area under the time-concentration curve, dose and peak plasma concentration, and peak plasma concentration and increase in QTc were linear (r = 0.66 to 0.92; p less than 0.001). QTc increases of approximately equal to 25% were seen at plasma concentrations of approximately equal to 2.0 micrograms/ml. The mean elimination half-life (+/- SD) was 3.6 +/- 0.8 hours, and most of a dose (77 +/- 13%) was recovered unchanged in the urine. Plasma concentrations greater than or equal to 0.8 micrograms/ml suppressed arrhythmias (5 patients) or aggravated them (3), including 1 patient who needed cardioversion for an episode of torsades de pointes (2.7 micrograms/ml). Thus, sematilide exerts class III actions in patients. Further studies to evaluate the role of this antiarrhythmic mode of action should be conducted at doses designed to limit QTc increases.