Frequency dependent effects of d-sotalol and amiodarone on the action potential duration of the human right ventricle

Frequency dependent effects of d-Sotalol (2.0 mg/kg IV, n = 6) and amiodarone (400 mg/day for 3 months, n = 9) were studied on the action potential duration (APD) in 14 patients who underwent electrophysiological testing. Monophasic action potentials were recorded from the right ventricle at five different steady-state paced cycle lengths (700 msec, 600 msec, 500 msec, 400 msec, and 350 msec), and during ventricular extrastimuli with coupling intervals between 300 msec and 1000 msec, before and after d-sotalol and amiodarone, respectively. D-sotalol caused a prolongation of the APD at slow steady-state stimulation rates (11 +/- 5% at cycle length of 700 msec), which became attenuated at faster cycle lengths (5 +/- 3% at cycle length of 350 msec). Prolongation of APD after amiodarone was independent of pacing rate, e.g., 12 +/- 9% at cycle length of 700 msec, and 11 +/- 6% at cycle length of 350 msec. Similar frequency dependent prolongation of the APD was observed during abrupt changes of cycle lengths after d-sotalol, whereas amiodarone caused uniform prolongation of the APD at different extrastimulus intervals. Thus, d-sotalol, a nonselective potassium channel blocker, has reverse use-dependent effects on the human ventricular APD, while amiodarone with greater potassium channel selectivity, has equal ability to prolong the ventricular APD at fast and slow heart rates.

Flecainide in quinidine-resistant atrial fibrillation

Flecainide (100 mg twice daily) was used for prevention of paroxysmal atrial fibrillation (PAF) in 52 patients with frequent symptomatic attacks that were resistant or intolerant to quinidine (600-900 mg/day). Underlying heart disease was present in only 8 cases and left ventricular ejection fraction was always greater than 30%. No patient had had a myocardial infarction. Vagally induced PAF was clinically documented in 35 patients. Amiodarone, previously used and ineffective, was combined with flecainide in 33 patients. After 1-5.8 years of follow-up, complete disappearance of PAF was observed in 38 patients (73%). The success rate was slightly higher in patients with vagally induced PAF (p = 0.07). Extracardiac side effects necessitated withdrawal in only 3 cases. Permanent pacemaker was needed in 7 patients on amiodarone and flecainide because of excessive sinus bradycardia. Two patients, with previously documented atrial flutter, experienced presyncopal episodes of atrial flutter with 1:1 atrioventricular (AV) conduction and wide QRS complex. No death occurred during the follow-up. In this series, quinidine proved to be unsuccessful in 46 patients and it was withdrawn in 6. We concluded that flecainide is efficient and well tolerated for long-term prevention of PAF in patients resistant to quinidine. The possibility of 1:1 AV conduction during atrial flutter may suggest the use of verapamil or beta blockers in combination with flecainide in patients with previously documented atrial flutter.

Effects of flecainide on atrial electrophysiology in the Wolff-Parkinson-White syndrome

The effects of intravenous flecainide and propafenone (2 mg/kg) administered in random order were compared in 16 patients with Wolff-Parkinson-White syndrome. Both agents prolonged significantly the anterograde refractory period of the pathway and caused complete anterograde block in the pathway in 5 patients. Atrial fibrillation was not inducible in 7 patients following both agents. Both drugs prolonged the minimum pre-excited RR interval, but this effect was significantly greater after flecainide than after propafenone. At a pacing cycle length of 500 msec, the atrial effective refractory period was unchanged after flecainide, but the atrial monophasic action potential duration, and the atrial monophasic action potential duration of the earliest inducible atrial beat were significantly increased. These results suggest that rate-dependent prolongation of atrial repolarization does not occur following clinical intravenous doses of flecainide. The prolongation of the repolarization of ectopic beats may prevent induction of atrial arrhythmias and may also have an important role in the termination of atrial fibrillation.

Effects of flecainide on the rate dependence of atrial refractoriness, atrial repolarization and atrioventricular node conduction in anesthetized dogs

Flecainide is effective against certain supraventricular arrhythmias (atrial fibrillation and atrioventricular [AV] node reentrant tachycardia), but its mechanisms of action are unknown. Previous in vitro work suggests that flecainide attenuates rate-dependent action potential duration shortening, producing tachycardia-dependent prolongation of the refractory period. This study was designed to assess whether similar changes occur in vivo and whether the effects of flecainide on AV node conduction depend on heart rate and on direction of propagation (anterograde vs. retrograde). The effects of flecainide at three clinically relevant concentrations were assessed in open chest, morphine-chloralose-anesthetized dogs. Flecainide increased atrial refractory period in a concentration- and rate-related fashion (e.g., dose 3 increased the atrial effective refractory period by 9 +/- 4% at a cycle length of 1,000 ms but by 36 +/- 5% and 55 +/- 10% at a basic cycle length of 400 and 300 ms, respectively; p less than 0.001 for each). Flecainide attenuated the action potential duration accommodation (measured by monophasic action potentials) to heart rate, causing tachycardia-dependent action potential duration prolongation and accounting for most of the rate-dependent atrial effective refractory period changes. Flecainide increased Wenckebach cycle length, but the concentration-response curve was much steeper in the retrograde (slope 41 +/- 7 ms/mumol.liter-1) than in the anterograde direction (17 +/- 4 ms/mumol.liter-1; p less than 0.01), indicating more potent effects on retrograde conduction. The depressant action of the drug on the AV node was also rate dependent, with an effect on the AH interval at a basic cycle length of 400 ms that averaged 1.8, 1.5 and 2 times that at a basic cycle length of 1,000 ms for doses 1 (p less than 0.05), 2 (p less than 0.01) and 3 (p less than 0.001), respectively.

CONCLUSIONS

1) Flecainide suppresses atrial action potential duration accommodation to heart rate changes in vivo, leading to rate-dependent atrial effective refractory period prolongation, which may be important in suppressing atrial fibrillation. 2) The drug has frequency- and direction-dependent effects on AV node conduction, which may lead to selective antiarrhythmic actions during AV node reentry.

On the mechanism of action of antiarrhythmic agents

Cardiac arrhythmias arise from disturbances in the functioning of the specific ion channels that normally control excitation or from the functional expression of previously latent channels. Antiarrhythmic agents act by blocking the membrane sodium, potassium, and calcium channels, but no agent has exclusive action on a given type of channel. Arrhythmias resulting from reentry form the largest group of clinically significant arrhythmias. Most arrhythmias result from depressed sodium channel function. The local anesthetic class of sodium channel blockers (class I agents) acts by slowing conduction and converting regions of unidirectional block to bidirectional block. Class III agents act by prolonging the action potential duration. Because potassium currents are normally responsible for repolarization of the cardiac action potentials, these agents are generally assumed to be potassium channel blockers. Class IV antiarrhythmics--calcium channel blockers--are used when a group of reentrant arrhythmias arises in regions in which conduction is primarily sustained by increases in permeability to calcium ions. The mechanisms of action of antiarrhythmic agents are discussed with respect to the basic cellular mechanisms of cardiac arrhythmias.

Effects of pinacidil on guinea-pig isolated perfused heart with particular reference to the proarrhythmic effect

1. The effects of pinacidil (10, 30, 50 microM) on contractility (+dP/dtmax), coronary perfusion pressure (cP), and ECG intervals (PR, QRS, QT) have been studied on constant-flow perfused guinea-pig hearts, driven at four frequencies (2.5, 3, 3.5, 4 Hz). 2. Pinacidil decreased +dP/dtmax, cP and the QT interval in a dose-dependent manner, whereas the PR interval was increased. QRS duration was not modified. All these effects were independent of driving frequency. Pinacidil decreased the interval from Q-wave to T-wave peak (QTpeak) to a greater extent than the QT interval, thus decreasing the QTpeak/QT ratio. This effect, unlike that on QT interval, was more evident at the highest frequency of stimulation. 3. In 4 out of 20 hearts treated with pinacidil sustained ventricular fibrillation (VF) occurred following a short run of premature ventricular beats (R on T phenomenon). 4. In separate experiments, an attempt to induce VF electrically was made at drug concentrations ranging from 10 microM to 100 microM (8 experiments for each concentration). In control conditions and at the lowest concentrations of pinacidil tested (10 microM) VF could never be induced; in the presence of 30 microM pinacidil VF was induced in 5 out of 8 experiments. Drug concentrations higher than 50 microM permitted the induction of VF in every case. 5. Although the concentrations of pinacidil producing ventricular fibrillation are 30-40 times higher than those found in patients under long term treatment with this agent, it is suggested that caution should be used in prescribing this drug, at least in patients suffering from myocardial ischaemia.

Effects of antiarrhythmic drugs on canine atrial flutter due to reentry: role of prolongation of refractory period and depression of conduction to excitable gap

Antiarrhythmic drugs prolong the effective refractory period and depress conduction. To determine the exact role played by these two electrophysiologic effects in the termination of reentry, the effects of disopyramide, flecainide, propafenone and E-4031, a new class III drug, were examined in a canine model of atrial flutter (cycle length 120 +/- 4 to 131 +/- 3 ms) caused by reentry. Atrial flutter was induced in 32 anesthetized open chest dogs after placement of an intercaval crush. The excitable gap ranged from 9 +/- 2% to 11 +/- 4% of the basic flutter cycle length. The effective refractory period in the reentrant circuit during atrial flutter was estimated by subtracting the excitable gap from the basic flutter cycle length. Prolongation of flutter cycle length by the test drugs was proportional to the interatrial conduction time (r = 0.87, p less than 0.001). Atrial flutter was terminated by each test drug in all dogs except for flecainide and propafenone in one dog each. E-4031 prolonged the refractory period during atrial flutter to 129 +/- 6 ms, which did not differ significantly from the flutter cycle length immediately before termination (134 +/- 4 ms). The refractory period during atrial flutter after injection of the other drugs was shorter than the flutter cycle length before termination of atrial flutter (for example, flecainide 126 +/- 5 vs. 179 +/- 11 ms, p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)

Serial antiarrhythmic drug treatment to maintain sinus rhythm after electrical cardioversion for chronic atrial fibrillation or atrial flutter

The sequential use of different types of antiarrhythmic drugs may improve arrhythmia prognosis in chronic atrial fibrillation or flutter after successful electrical cardioversion. The rationale for serial treatment is that the arrhythmogenic mechanism may vary between patients, leading to different responses to 1 specific drug. To investigate this issue prospectively, 127 patients having chronic fibrillation or flutter exclusively, underwent serial drug treatment with flecainide (stage I) followed by sotalol or, if contraindicated, quinidine (stage II) and eventually amiodarone (stage III). Stages II and III were entered after electrical recardioversion for a recurrence during stages I or II, respectively. Calculated on an actuarial basis, the 2-year cumulative percentage of patients free of the arrhythmia increased from 31% after stage I to 63% at the end of serial treatment. To reach this result, a mean of 1.8 +/- 0.8 cardioversions per patient were needed, with 53 patients progressing to stage II and 34 to stage III. Sixteen patients stopped serial treatment prematurely and 15 patients were considered to have intractable atrial fibrillation at the end of stage III. Incidence of proarrhythmia was low. Multivariate analysis disclosed that an older age, in combination with a large number of previous episodes of arrhythmia, a long previous duration of arrhythmia and presence of mitral valve disease, were predictive for medical refractoriness during serial treatment. It is concluded that serial treatment may improve arrhythmia prognosis in atrial fibrillation or flutter, with an acceptable incidence of proarrhythmic events.

Clinical electrophysiological effects of intravenous recainam: an antiarrhythmic drug under investigation for the treatment of ventricular and supraventricular arrhythmias

This open-label, multicenter study was designed to assess the electrophysiological properties of intravenous recainam, an investigational Class I antiarrhythmic agent. In 25 patients undergoing electrophysiological studies for the evaluation of arrhythmias, recainam was administered intravenously in a loading infusion (0.1 mg/kg/min) for 40 minutes, followed by a maintenance infusion (0.02 mg/kg/min) until the completion of the study. Electrophysiological measurements were obtained at baseline, 30 minutes after initiation of the loading infusion, and 30 minutes after termination of the infusion during washout. Conduction intervals, refractory periods, and sinus node recovery times were measured during sinus rhythm and during atrial or ventricular pacing. Vital signs were obtained and recorded before, during, and after recainam infusion. The results showed no change in mean arterial pressure, but heart rate increased slightly by 4 beats/min following recainam infusion. Recainam produced a generalized slowing of intracardiac conduction. The mean intraatrial conduction time, measured at an atrial paced cycle length of 600 msec, increased during recainam loading infusion by 44%, from 38.8% +/- 2.8 to 53.0 +/- 5.4 msec; intranodal conduction time increased by 10%, from 102.0 +/- 5.5 to 112.1 +/- 5.2 msec; and infranodal conduction time increased by 31% from 53.1 +/- 3.0 to 70.7 +/- 3.8 msec. Slowed conduction persisted during washout. The mean right atrial effective refractory period was significantly prolonged (+7% at 600 msec cycle length and +8% at 450 msec cycle length, P less than 0.05 and P less than 0.01, respectively) during recainam loading and remained so during washout.(ABSTRACT TRUNCATED AT 250 WORDS)

Time course of moricizine's effect on signal-averaged and 12 lead electrocardiograms: insights into mechanism of action

The mechanism of action of moricizine, a new antiarrhythmic agent used in the Cardiac Arrhythmia Suppression Trial, is incompletely characterized. In addition, because moricizine is extensively metabolized, plasma moricizine concentration has an unknown relation to myocardial drug effect. Signal-averaged and standard electrocardiograms (ECGs) were used to monitor moricizine's myocardial effects in 16 patients with frequent ventricular premature complexes taking 600 to 900 mg daily. Three signal-averaged ECG variables were measured: total filtered QRS duration (fQRS), root-mean-square voltage in the terminal 40 ms of the QRS complex (V40) and the terminal low amplitude duration less than 40 microV (LAS). At steady state, plasma samples were collected and serial recordings of signal-averaged and standard ECGs were taken at 0, 1, 2, 4, 6 and 8 h after moricizine administration. A 24 h ambulatory ECG was recorded throughout the test period. Moricizine prolonged the fQRS (p less than 0.05) and decreased the V40 (p less than 0.05) of the signal-averaged ECG and prolonged the QRS (p less than 0.05) and corrected JT (JTc) intervals (p less than 0.05) of the standard ECG. The time course of the signal-averaged and standard ECG variables paralleled plasma moricizine concentration; that is, the maximal changes occurred at 1 to 2 h and declined to time 0 values at 8 h. The maximal changes were: fQRS (+8%), V40 (-33%), QRS (+8%) and JTc (+4%). Thus, dynamic changes were observed for intraventricular conduction (fQRS, QRS) and ventricular repolarization (JTc) over the dosing interval.(ABSTRACT TRUNCATED AT 250 WORDS)

Serum CA 125 levels in early pregnancy and subsequent spontaneous abortion

Cardiovascular diseases are the most common causes of human morbidity and mortality despite significant therapeutic improvements by surgical, interventional and pharmacological approaches in the last decade. MicroRNAs (miRNAs) are important and powerful mediators in a wide range of diseases and thus emerged as interesting new drug targets. An array of animal and even human miRNA-based therapeutic studies has been performed, which validate miRNAs as being successfully targetable to treat a wide range of diseases. Here, the current knowledge about miRNAs therapeutics in cardiovascular diseases on their way to clinical use are reviewed and discussed.

[Scanning electron microscopy studies in the detection of apo-B,E receptor activity of the lymphocyte membrane for diagnostic verification of genetically determined disorders of lipid metabolism]

We present a scanning electron microscopic method for determining the quantity of the apo B,E-receptors at the surface of lymphocytes. We used human lymphocytes from venous blood. Gold particles, 50 nm in diameter, were conjugated to the receptors by indirect coupling. We visualized the gold particles by means of an electron microscope (JEM 100 S with scanning attachment ASID). The lymphocytes of control persons and of patients with primary hyperlipoproteinaemias were analysed. Scanning electron microscopic assay of labelled apo-B,E-receptors was shown to allow the rapid and accurate identification of patients with autosomal monogenic hypercholesterolaemia.