Relationship between plasma levels of procainamide, suppression of premature ventricular complexes and prevention of recurrent ventricular tachycardia

Management of patients with an electrical storm or clustered ventricular arrhythmias: a clinical consensus statement of the European Heart Rhythm Association of the ESC-endorsed by the Asia-Pacific Heart Rhythm Society, Heart Rhythm Society, and Latin-American Heart Rhythm Society

Electrical storm (ES) is a state of electrical instability, manifesting as recurrent ventricular arrhythmias (VAs) over a short period of time (three or more episodes of sustained VA within 24 h, separated by at least 5 min, requiring termination by an intervention). The clinical presentation can vary, but ES is usually a cardiac emergency. Electrical storm mainly affects patients with structural or primary electrical heart disease, often with an implantable cardioverter-defibrillator (ICD). Management of ES requires a multi-faceted approach and the involvement of multi-disciplinary teams, but despite advanced treatment and often invasive procedures, it is associated with high morbidity and mortality. With an ageing population, longer survival of heart failure patients, and an increasing number of patients with ICD, the incidence of ES is expected to increase. This European Heart Rhythm Association clinical consensus statement focuses on pathophysiology, clinical presentation, diagnostic evaluation, and acute and long-term management of patients presenting with ES or clustered VA.

Pharmacologic Management for Ventricular Arrhythmias: Overview of Anti-Arrhythmic Drugs

Ventricular arrhythmias (Vas) are a life-threatening condition and preventable cause of sudden cardiac death (SCD). With the increased utilization of implantable cardiac defibrillators (ICD), the focus of VA management has shifted toward reduction of morbidity from VAs and ICD therapies. Anti-arrhythmic drugs (AADs) can be an important adjunct therapy in the treatment of recurrent VAs. In the treatment of VAs secondary to structural heart disease, amiodarone remains the most well studied and current guideline-directed pharmacologic therapy. Beta blockers also serve as an important adjunct and are a largely underutilized medication with strong evidentiary support. In patients with defined syndromes in structurally normal hearts, AADs can offer tailored therapies in prevention of SCD and improvement in quality of life. Further clinical trials are warranted to investigate the role of newer therapeutic options and for the direct comparison of established AADs.

Pharmacokinetic determinants for the right dose of antiarrhythmic drugs

INTRODUCTION

Antiarrhythmic drugs (AADs) show a narrow therapeutic range and marked intersubject variability in pharmacokinetics (PK), which may lead to inappropriate dosing and drug toxicity.

AREAS COVERED

The aim of the present review is to describe PK properties of AADs, discussing the main changes in different clinical scenarios, such as the elderly and patients with obese, chronic kidney, liver, and cardiac disease, in order to guide their right prescription in clinical practice.

EXPERT OPINION

There are few data about PK properties of AADs in a special population or challenging clinical setting. The use and dose of AADs is commonly based on physicians' clinical experience observing the clinical effects rather than being personalized on the individual patients PK profiles. More and updated studies are needed to validate a patient centered approach in the pharmacological treatment of arrhythmias based on patients' clinical features, including pharmacogenomics, and AAD pharmacokinetics.

The Clinical Significance of the Pharmacogenetics of Cardiovascular Medications

Inter-individual variability in the response to numerous drugs can be traced to a number of sources. One source of variability in drug response is the variability associated with the metabolic capacity of an individual. The component of metabolic capacity that will be the focus of this article is that determined by heredity. Pharmacogenetics is frequently referred to as the study of the effects of heredity on the disposition and response to medications. This article will review the pharmacokinetic and pharmacodynamic significance of pharmacogenetics as it pertains to a select number of cardiovascular agents. The enzyme systems responsible for drug metabolism discussed in this article will be limited to the P-450IID6 and N-acetylation pathways. Given the extensive use of cardiovascular agents in clinical practice that are affected by this genetic polymorphism, it is important for the practicing pharmacist to be aware of this phenomenon and its implications. Hopefully, the knowledge gained from this article will help practicing pharmacists to appreciate the clinical significance of polymorphic drug metabolism and provide a basis for the application of this knowledge to a variety of practice settings.

Effects of incremental doses of procainamide in patients with sustained uniform ventricular tachycardia

INTRODUCTION

Although intravenously administered procainamide has been used extensively during electropharmacologic testing for more than 10 years, there is little information available on the effects of incremental dosing of procainamide in patients with inducible, monomorphic ventricular tachycardia (VT).

METHODS AND RESULTS

Twenty-nine patients with coronary artery disease had sustained monomorphic VT reproducibly induced in the baseline, drug-free state. Programmed stimulation was repeated 5 minutes after loading infusion (50 mg/min) of 7.5 and 15 mg/kg (all patients) and 22.5 mg/kg of procainamide (15 patients), while maintaining continuous infusion of 0.055, 0.11, and 0.165 mg/kg per minute after each increment in dose, respectively. Corresponding procainamide plasma concentrations were 5.6 +/- 2, 10.5 +/- 3, and 14.5 +/- 3 mg/L before, and 4.7 +/- 2, 9.6 +/- 3, and 14.6 +/- 4 mg/L after electrophysiologic study at each increment in dose of procainamide, respectively. Each incremental dose of procainamide resulted in significant prolongation of tachycardia cycle length and QRS duration during sinus rhythm and right ventricular pacing. Five (17%), 7 (24%), and 1 (7%) patients, respectively, had no inducible sustained VT following the incremental dosing of procainamide. Three of five patients who had no inducible VT at 7.5 mg/kg had VT induced again at a higher dose of procainamide. Four of 24 patients whose VT remained inducible at 7.5 mg/kg of procainamide had no VT induced at 15 mg/kg of procainamide. Twelve (41%), 15 (52%), and 6 (40%) patients, respectively, no longer had VT with baseline morphology induced following the incremental dosing of procainamide. VT with new morphology compared to baseline was induced in more than 40% of patients at one or more of the three different procainamide dosing regimens. The mean cycle length of VTs with new morphology was significantly shorter than the cycle length of tachycardias with baseline morphology at each particular dose of procainamide.

CONCLUSION

Similar serum procainamide concentrations before and after programmed stimulation can be achieved at the described dosing regimen. Although 7.5 and 15 mg/kg of procainamide are both effective in suppressing induction of all VT in 20% to 25% of patients, non-inducibility at a particular dose of procainamide does not predict noninducibility at a respectively higher or lower dose. New morphologies of VT that are frequently faster than VTs with baseline morphology at a particular dose of procainamide can be induced in approximately half of the patients, and the clinical significance of these arrhythmias remains to be determined.

Ventricular arrhythmias induced by programmed ventricular stimulation after uncomplicated myocardial infarction

The aim of this study was to correlate the occurrence of ventricular dysrhythmias induced by programmed ventricular stimulation and sudden cardiac death (SCD) after a first episode of acute myocardial infarction (AMI). Twenty-seven consecutive male patients aged fifty-four +/- six (forty-seven to seventy) years were studied prospectively. Thirty days after AMI, patients were submitted to coronary arteriography and programmed ventricular stimulation with the S2-S3-S4 protocol. Noninvasive assessments, including Holter monitoring, ECG stress test, and radionuclide ejection fraction, were also repeated six and twelve months after AMI. Ventricular dysrhythmias were induced in all patients. According to such response, patients were divided into three groups: (1) repetitive ventricular response (n = 9); (2) nonsustained ventricular tachycardia (n = 8); and (3) sustained ventricular tachycardia (n = 10). All patients consistently developed complex ventricular dysrhythmias at Holter monitoring and ECG stress test. One patient from group 2 suffered SCD and another presented a syncope. Similarly, in group 3, 2 patients suffered SCD, 1 during a documented episode of recurrent AMI. Except for 1 patient, radionuclide ejection fraction remained unchanged throughout the study in all cases. SCD was also unrelated to the presence and type of dysrhythmias at noninvasive evaluation. Therefore, the type of ventricular dysrhythmia induced by the S2-S3-S4 protocol has no correlation with late SCD in patients with a first AMI and preserved ejection fraction.

Comparison of QRS morphologies of spontaneous premature ventricular complexes and ventricular tachycardia induced by programmed stimulation

We addressed the hypothesis that premature ventricular complexes (PVCs) and sustained ventricular tachycardia (VT) have identical QRS morphologies in 20 patients with recurrent sustained VT. Continuous six-lead ECGs of PVCs and sustained VT induced with programmed stimulation were recorded. A computer program divided the PVCs and VT beats of each patient into distinct morphologic groups and a representative waveform was obtained by averaging the PVC and VT beats of the group members. A correlation coefficient was then derived between the QRS complexes of each PVC and VT morphology. The mean number of PVC morphologies was 12 +/- 8 per patient (range 1 to 26), the mean number of VT morphologies was 2 +/- 1 per patient (range 1 to 5). The correlation coefficient between the dominant PVC morphology and a VT morphology was greater than 0.7 in only three patients. The combined percent contribution of all PVCs with morphologies that were at least possibly identical to those of VT averaged only 13%. Thus PVCs with morphologies identical to those of VT are present in some patients with sustained VT, but these constitute a small proportion of all PVCs.

Reversal of proarrhythmic effects of flecainide acetate and encainide hydrochloride by propranolol

The use of membrane-active antiarrhythmic agents may be complicated by aggravation of existing arrhythmias or development of new drug-induced arrhythmias. Four patients, referred because of out-of-hospital cardiac arrest or symptomatic sustained ventricular tachycardia, were receiving class IC antiarrhythmic agents in an attempt to prevent inducibility of sustained ventricular tachycardia. New or worsening spontaneous arrhythmias developed while they were on flecainide acetate (n = 3) or encainide hydrochloride (n = 1) therapy. Spontaneous runs of rapid nonsustained and sustained ventricular tachycardia developed in two. Increased frequency of premature ventricular contractions and repetitive forms of ventricular ectopic activity developed in one, despite the fact that inducibility of sustained ventricular tachycardia had been prevented. Salvos and nonsustained ventricular tachycardia developed in the fourth patient. Propranolol had failed to prevent inducibility of sustained ventricular tachycardia during previous programmed stimulation studies in three of the four patients, but it reproducibly suppressed drug-induced arrhythmias that appeared only after administration of the IC agents in each patient. Suppression of the proarrhythmic effects by beta-adrenergic blockade suggests a possible interaction of these drugs with autonomic function in the genesis of the observed proarrhythmic effects. Direct pharmacologic control of proarrhythmic drug effects has not previously been reported.

Effects of lidocaine and quinidine on post-repolarization refractoriness after the basic and premature action potentials: consideration of aim of antiarrhythmic drug therapy

Antiarrhythmic drugs are often more effective in suppressing ventricular tachycardias than are background premature extrasystoles. The mechanism of action of these agents was examined by studies on the effects of lidocaine and quinidine on post-repolarization refractoriness of both basic and premature action potentials. In the absence of antiarrhythmic drugs, the excitability threshold was relatively constant after the end of repolarization of both basic and premature action potentials. In the presence of lidocaine or quinidine, the strength-interval curves were shifted to the right and superiorly, and the two drugs had different effects on the course of the strength-interval curve and Vmax recovery, presumably due to use-dependent V max block. Moreover, depressions of Vmax and excitability were more marked after the premature action potential than after the basic action potential. These results suggest that lidocaine and quinidine cause more depression of the excitability of second premature contractions than of first premature contractions, and also indicate that for protection against sustained ventricular tachycardias, it may not be necessary to suppress chronic premature ventricular contractions.

Sudden cardiac death: etiologies, pathogenesis, and management

Sudden death claims an estimated 350,000 lives per year in the United States. When death occurs within 1 hour of the onset of symptoms, 90% are the result of ventricular tachyarrhythmias. The majority of victims are middle-aged men with coronary artery disease, but in approximately 25%, sudden death is the presenting manifestation of their problem. In some populations, the detection of premature ventricular complexes (PVCs) by ambulatory monitoring is predictive of an increased risk of sudden death. However, the arrhythmia that best predicts this risk is unclear, and ambient arrhythmias are only a modest marker of this risk. Therapy to suppress asymptomatic PVCs has not been shown to be effective in preventing sudden death, and in some cases, lethal arrhythmias can be prevented without significant effects on ambient arrhythmias. Other risk markers such as depressed left ventricular function and the presence of low-amplitude, long-duration, late potentials recorded on a signal averaged electrocardiogram are more powerful predictors of risk than are PVCs. These latter findings in particular support the presence of areas of slow electrical conduction (a requirement for reentrant mechanism arrhythmias) and suggest that an abnormal electrical environment or "substrate" is the most important factor in this problem. The management of patients at risk for sudden death is controversial. While postinfarct survivors with arrhythmias constitute a population at increased risk, the absolute risk is only about 5% in the first year and has not been shown to be improved by conventional antiarrhythmic drugs. Small study size, arrhythmia variability, ill-defined end points, and proarrhythmia may partially explain this apparent lack of efficacy. The prophylactic use of antiarrhythmic drugs other than beta-blockers to prevent sudden death in asymptomatic populations at risk is therefore of unproven benefit. By contrast, patients who have survived a life-threatening arrhythmia unrelated to an acute myocardial infarction have an approximately 30% risk of recurrence in the following year. In these patients, the use of ambulatory monitoring to guide therapy is limited by the high incidence of false-negative responses (lethal arrhythmia recurrence despite ambient arrhythmia suppression) and the lack of frequent spontaneous arrhythmias in many patients. In this patient population, electrophysiological testing can be used to prognosticate recurrence and gain insight into arrhythmia mechanism, stability, and hemodynamic tolerance. The technique is also useful in guiding both pharmacological and nonpharmacological therapy.(ABSTRACT TRUNCATED AT 400 WORDS)

Pharmacokinetics and dromotropic activity of ajmaline in rats with hyperthyroidism

1. The pharmacokinetics and the dromotropic action (increased PQ interval) of intravenously administered ajmaline (2 mg kg-1) were studied in hyperthyroid rats with sinus tachycardia. The hyperthyroidism was induced by intraperitoneal injection of 3,5,3'-triiodo-L-thyronine (0.5 mg kg-1) for 4 days. 2. The change in the ajmaline concentration in whole blood could be described by a biexponential equation. The steady state distribution volume of ajmaline decreased from 4.81 l kg-1 in control rats to 3.80 l kg-1 in hyperthyroid rats and the total body blood clearance was slightly higher in hyperthyroid rats than in control rats. 3. Ajmaline exhibited a saturable binding to rat plasma proteins, and one kind of binding site was found in the observed range of concentrations. The binding capacity was 2 fold higher in hyperthyroid rats than in control rats. 4. On the basis of the plasma unbound concentration, ajmaline exhibited an increased negative dromotropic activity in hyperthyroid rats compared with control rats. 5. A positive correlation was found between the pacing rate and the dromotropic action of ajmaline on atrioventricular conduction in isolated perfused hearts. There was no significant difference in the rate-dependence of the effect of ajmaline on the heart between control and hyperthyroid rats. 6. Our findings suggest that the increased dromotropic activity of ajmaline is mainly due to the increased heart rate in hyperthyroid rats.

Spontaneous compared with induced onset of sustained ventricular tachycardia

Electrophysiological characteristics of the modes of initiation of 16 episodes of spontaneously occurring sustained ventricular tachycardia recorded in 16 patients by two-channel ambulatory electrocardiographic monitoring were compared with the characteristics of ventricular tachycardia induced by programmed electrical stimulation. Eleven episodes of spontaneous ventricular tachycardia began after a single ventricular premature depolarization (VPD), three episodes after two VPDs, and two episodes after five VPDs. By comparison, only four episodes of sustained ventricular tachycardia were induced with a single VPD. Each episode of spontaneous ventricular tachycardia was initiated by a late coupled VPD (RR':QT ratio greater than 1.0). The VPD was often morphologically similar to the ensuing ventricular tachycardia (eight of 11 episodes that began after a single VPD). No correlation was found between the modes of initiation of spontaneous and induced ventricular tachycardia. We hypothesize that concealed decremental slow conduction, reflected in the long coupling intervals of VPDs initiating ventricular tachycardia, is of critical importance in initiating ventricular tachycardia. We conclude that major differences exist in the timing and number of VPDs associated with the onsets of spontaneous and induced sustained ventricular tachycardia.

The premise, promise, and perils of the prevention of lethal ventricular tachyarrhythmias

Sudden cardiac death caused by ventricular tachyarrhythmias claims about 360,000 lives a year in the United States. The premature ventricular complex (PVC) hypothesis has been the cornerstone for understanding this problem, but it is now recognized as an incomplete explanation for this catastrophy. The recognition of the importance of structural heart disease in this process has led to the development of the Substrate Hypothesis as an alternative explanation. In this construct, PVCs may trigger lethal arrhythmias but only if an abnormal electrophysiologic substrate is present. This hypothesis more completely describes the pathophysiology of the process, provides the basis for understanding the value and limitations of the techniques used for risk assessment and management, and helps clarify the potential endpoints and potential adverse effects of therapy to prevent arrhythmias. Since no single diagnostic technique is ideal and no therapeutic modality is universally effective, an approach to the management of this problem must be multidimensional and based on a firm understanding of the actual risk of a life threatening arrhythmia, the potential but unproven benefits and uncertain endpoints of drug therapy, the cost, and the potential for arrhythmia exacerbation or significant side effect.

QRS morphology-dependent pharmacodynamics in multiform ventricular ectopic activity

The effect of an infusion of intravenous procainamide on the frequency of ventricular premature complexes (VCPs) of differing QRS morphologies was studied in 20 patients with multiform ectopic activity. In 17 of 20 patients, there was differential suppression of single VPCs with different QRS morphologies. VPCs of the most frequent QRS morphology and the second most frequent QRS morphology were compared with respect to the procainamide level at the escape of VPCs from 85% suppression and the duration of suppression measured from the onset of the procainamide infusion. In 8 patients, VPCs of the most frequent QRS morphology remained suppressed at lower procainamide concentrations and for longer times than did VPCs of the second most frequent QRS morphology (escape procainamide concentration = 2.8 +/- 1.7 versus 5.4 +/- 2.3 micrograms/ml, p less than 0.025; time to escape 244 +/- 138 versus 98 +/- 114 min; p less than 0.05). In 9 other patients, VPCs of the second most frequent QRS morphology remained suppressed at lower procainamide concentrations and for longer times than did VPCs of the most frequent QRS morphology (escape procainamide concentration 2.9 +/- 1.4 versus 8.3 +/- 6.3 micrograms/ml, p less than 0.025; time to escape 317 +/- 114 versus 63 +/- 80 min; p less than 0.001). Thus, in individual patients there are specific patterns of suppression of VPCs of different QRS morphologies which are independent of the frequency of each morphology. There is apparently a differential pharmacologic effect of procainamide on the foci or pathways responsible for the different QRS morphologies of multiform VPCs.

Sustained therapeutic efficacy and safety of oral propafenone for treatment of chronic ventricular arrhythmias: a 2-year experience

Thirty-two men with chronic ventricular arrhythmias responded to propafenone, a new potent antiarrhythmic agent, in short-term trials with 85% or greater reduction of total ventricular premature complexes (VPCs) per hour, 95% or greater reduction of ventricular couplets (VCs) per hour, and 100% abolition of ventricular tachycardia (VT) beats per 24 hours. These patients were continued on long-term propafenone therapy to assess sustained therapeutic efficacy and safety. Thirty patients completed 1 year and 26 patients completed 2 years of testing with this agent; one patient died of sudden death and another died of a noncardiac cause. Although there were significantly fewer patient responders at 1 and 2 years, the majority of patients (greater than 79%) continued to respond optimally to propafenone. Side effects were minor and included bitter taste, dizziness, congestive heart failure, fatigue, and significant prolongation of the PR and QRS intervals. Propafenone has sustained antiarrhythmic efficacy after 2 years without serious toxicity.

Spontaneous variability in the frequency of ventricular premature complexes over prolonged intervals and implications for antiarrhythmic treatment

Spontaneous variability in the frequency of premature ventricular complexes (VPCs) during ambulatory electrocardiography was examined over short (2- to 14-day) and long (6- to 12-month) periods in 20 patients. The coefficient of variation of the mean daily VPC frequency was significantly lower in the short-term periods than the long-term periods. The 95% confidence limit for spontaneous variation in mean daily arrhythmia frequencies was estimated with a linear regression method comparing two 1-day electrocardiographic recordings. The relative reduction in VPCs reaching the confidence limit calculated from the short-term periods was 69% at the beginning and 73% at the end of the 6- to 12-month follow-up. Corresponding values for repetitive VPCs were 78% and 77%. In comparing 2 recordings separated by the long interval, the reductions required were 98 to 100% for all VPCs, and even a 100% reduction was not significant for repetitive VPCs. The number of VPCs fell spontaneously below the initial confidence limit in 8 of 20 patients in later assessments. Thus, apparently positive individual responses are achieved in long-term treatment studies if stringent efficacy criteria are not followed. The variability between recordings over short periods remains fairly constant when reassessed after a long interval, even if the frequency of arrhythmias changes over the long interval. This permits application of conventional percentage limits in evaluation of therapeutic effects if the natural extent of the arrhythmias is periodically reassessed.

Comparison of the characteristics of nonsustained ventricular tachycardia on Holter monitoring and sustained ventricular tachycardia observed spontaneously or induced by programmed stimulation

The characteristics of nonsustained ventricular tachycardias (VT) on Holter monitor recordings were compared with the characteristics of sustained VT noted spontaneously or induced by programmed stimulation in 50 patients with a history of spontaneous sustained VT. At baseline before antiarrhythmic therapy, all patients had nonsustained VT (triplets or longer) on Holter recordings and sustained VT inducible by programmed stimulation. The mean rate of the fastest nonsustained VT on Holter monitoring (150 +/- 52 beats/min) was significantly slower that that of induced sustained VT (246 +/- 56 beats/min) (p less than 0.001). Compared with nonsustained VT on Holter monitoring, sustained VT by programmed stimulation were faster in 45 of 50 patients, similar in 2 and slower in 3. There was a poor correlation between the rates of nonsustained VT and sustained VT (r = 0.2195). The duration of the longest nonsustained VT was fewer than 6 beats in 24 patients and 6 beats or more in 26. The mean rates of induced sustained VT were not significantly different between patients with shorter (fewer than 6 beats) and longer (6 or more beats) nonsustained VT. In 12 patients, the rate of spontaneous sustained VT was available. The rate of spontaneous sustained VT (217 +/- 59 beats/min) was similar to that of sustained VT by programmed stimulation (277 +/- 60 beats/min). There was a close correlation (r = 0.8036) between the rates of spontaneous and induced sustained VT. However, the rate of nonsustained VT on Holter monitoring (151 +/- 76 beats/min) was significantly slower than the rate of spontaneous sustained VT (p = 0.002).(ABSTRACT TRUNCATED AT 250 WORDS)

Procainamide, disopyramide and quinidine: discordant antiarrhythmic effects during crossover comparison in patients with inducible ventricular tachycardia

A crossover comparison of intravenous procainamide, disopyramide and quinidine was made in 32 patients. All three drugs had dosage-related effects on electrocardiographic intervals, refractory periods and cycle length of ventricular tachycardia. Significant linear relations between serum drug levels and changes in refractory periods and ventricular tachycardia cycle length were also observed. Ventricular tachycardia was no longer inducible on at least one drug in 11 patients but concordance of this effect on both of the others was 36% and on either of the others it was 45%. Ventricular tachycardia remained inducible on at least one drug in 28 patients and concordance of this effect on both of the others was 75% and on either of the others was 79%. Continued inducibility on quinidine, the drug producing the greatest electrophysiologic effects, was the best individual predictor of continued inducibility on the others. Subdivision of continued inducibility into easier to induce, inducibility unchanged, or harder to induce dramatically decreased concordance of this effect. Thus the antiarrhythmic effects of these drugs are discordant in individual patients despite electrophysiologic similarities. Nevertheless, continued inducibility after high dosages of any one of these drugs is clinically useful for screening for continued inducibility on the others and this is dose-related rather than drug specific.

The Inotropic Actions of N-Acetylprocainamide: Blockade and Reversal by Propranolol

The inotropic actions of N-acetylprocainamide (NAPA) were studied in chloralose-urethane anesthetized dogs. Myocardial contractile force was measured with a Walton-Brodie strain gauge sutured to the right ventricle. A low-dose NAPA infusion (12 mg/kg i.v.) increased myocardial force by a maximum of 11.6±2.4% (mean±SEM), whereas a high dose of NAPA (60 mg/kg i.v.) increased myocardial force by 33.3±2.6% at the peak of the effect. The high-dose NAPA infusion also caused significant reductions in heart rate and blood pressure, while the low-dose NAPA infusion lacked significant chronotropic or hypotensive actions. Pretreatment with propranolol (0.5 mg/kg i.v. loading, followed by a 10 μg/kg/min infusion) did not block the positive inotropic actions of NAPA 12 mg/kg, but these actions were blocked in dogs pretreated with both propranolol and atropine (1 mg/kg). On the other hand, pretreatment with propranolol blocked and reversed the inotropic actions of NAPA 60 mg/kg, and potentiated its negative chronotropic effects. Thus, the positive inotropic actions of NAPA are indirect and more than one mechanism is involved; a component due to direct action related to the lengthening of cardiac repolarization is not discounted. At low doses, the increase in myocardial force seems related to NAPA's vagolytic properties, whereas at high doses the positive inotropic actions appear to be catecholamine-mediated. Furthermore, a negative inotropic action of high-dose NAPA is apparent after beta-adrenergic receptor blockade.

Antitachycardia strategies

The development of an antitachycardia strategy requires a cascade of assessments and decisions. The patient's problem and level of risk must be assessed in order to determine the goals of therapy. Empirical therapy is appropriate in low-risk situations, and during that ultimate emergency, the treatment of cardiac arrest. Quantitative objective assessment of therapeutic efficacy is indicated in most other situations. Such assessments may be primarily passive, such as recording of drug blood levels or serial Holter monitoring; or provocative, as in serial electrophysiologic, exercise, or psychological stress testing. Selection of an antiarrhythmic modality requires a balance between the risk of therapy and the risks related to the arrhythmia. Any antitachycardia strategy must also consider relative costs, and regulatory and reimbursement policies.

Long-term continuous electrocardiographic recordings and electrophysiologic testing to select patients with ventricular arrhythmias for drug trials and to determine antiarrhythmic drug efficacy

Long-term continuous electrocardiographic recordings (Holter recordings) and electrophysiologic testing are useful for selecting patients for antiarrhythmic drug trials and for evaluating efficacy and adverse effects during therapy. These 2 methods are used to establish patient eligibility and to stratify patients during randomization. Both noninvasive testing and electrophysiologic studies help to classify arrhythmias as benign, potentially malignant or malignant. Holter monitoring and electrophysiologic studies each have unique advantages and disadvantages for baseline evaluation before starting antiarrhythmic drug treatment and for evaluation of efficacy or adverse effects during follow-up. Both methods have been shown to predict outcome of treatment in patients with malignant ventricular arrhythmias (i.e., can be used as surrogates for sudden death). Several ongoing studies are attempting to extend our knowledge of these 2 techniques. A multicenter study in the United States is comparing the 2 methods for applicability, predictive accuracy and cost. Investigators in the Netherlands are testing the validity of electrophysiologic studies by continuing antiarrhythmic drug treatment whether or not programmed ventricular stimulation predicts success or failure. Finally, new proposals have been made for conducting randomized, controlled studies in selected patients with malignant ventricular arrhythmias using time to drug failure as the endpoint.

Recainam, a potent new antiarrhythmic agent: effects on complex ventricular arrhythmias

The antiarrhythmic efficacy and safety of intravenous recainam, a newly synthesized compound displaying potent class I antiarrhythmic activity, were tested in 10 hospitalized patients with frequent (greater than 30/h) complex ventricular ectopic beats. There were seven men and three women of average age 57 years (range 21 to 74); five had ischemic heart disease, three had cardiomyopathy and two had valvular heart disease. Recainam was given as a 3.0 mg/kg per 40 min loading infusion followed by a 0.9 mg/kg per h maintenance infusion over a 24 hour observation period. Arrhythmia response was assessed both in the short term (comparing 2 hours before and 1 hour after drug loading) and in the long term (comparing 48 hours before drug loading and 23 hours of maintenance infusion). The median frequency of total premature ventricular complexes decreased in the short term by 99.6% (from 392.5 to 1.5/h, p less than 0.005) and in the long term by 99.7% (from 435 to 1.3/h, p less than 0.01). Repetitive beats were suppressed by a median of 100% both in the short term (p less than 0.006) and during 24 hour infusion (from 80.9 to 0/h, p less than 0.003). More than 90% suppression of repetitive beats occurred in all 10 patients (100%) and more than 90% suppression of total arrhythmias occurred in 9 patients (90%) during the maintenance period. Electrocardiographic PR and QRS intervals increased by 19% (p less than 0.001) and 24% (p less than 0.003), respectively, during therapy, but the JTc interval decreased (p less than 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)

Procainamide pharmacokinetics in patients with acute myocardial infarction or congestive heart failure

Abnormal procainamide pharmacokinetics (prolonged half-life and decreased volume of distribution) and pharmacodynamics (decreased threshold for the suppression of premature ventricular complexes) have been suggested in patients with acute myocardial infarction or congestive heart failure, or both. To better define procainamide kinetics, 37 patients in the acute care setting received intravenous procainamide (25 mg/min, median dose 750 mg) with peak and hourly blood samples taken over 6 hours. Compared with the 10 control patients, the 12 patients with acute myocardial infarction and the 15 patients with congestive heart failure had normal procainamide pharmacokinetics with respect to half-life (2.3 +/- 1.0, 2.5 +/- 0.9 and 2.6 +/- 0.8 hours, respectively), volume of distribution (1.9 +/- 0.7, 1.8 +/- 0.4 and 1.8 +/- 0.5 liters/kg, respectively), clearance (11.3 +/- 7.5, 9.3 +/- 3.6 and 9.1 +/- 3.5 ml/min per kg, respectively) and unbound drug fraction (66 +/- 9, 66 +/- 9 and 69 +/- 4%, respectively). Low thresholds for greater than 85% premature ventricular complex suppression were confirmed in these patients (median 4.7 micrograms/ml in patients with acute myocardial infarction and 3.3 micrograms/ml in patients with congestive heart failure). Thus, differences in the response of premature ventricular complexes to procainamide reflect electropharmacologic differences dependent on clinical setting rather than pharmacokinetic abnormalities. Furthermore, the reduction of procainamide dosing in patients with acute myocardial infarction or congestive heart failure, based solely on prior kinetic data, may result in inappropriate antiarrhythmic therapy.

Coronary venous retroinfusion of procainamide: a new approach for the management of spontaneous and inducible sustained ventricular tachycardia during myocardial infarction

The efficacy of retrograde coronary venous delivery of procainamide for the management of spontaneous and inducible sustained ventricular tachycardia was evaluated and compared with systemic intravenous procainamide administration in 22 conscious dogs with permanent left anterior descending coronary artery occlusion. Selective retrograde injection of procainamide was achieved through an autoinflatable balloon catheter placed in the great cardiac vein, with the tip positioned in the vicinity of the site of left anterior descending coronary occlusion. Great cardiac vein retroinfusion of procainamide was significantly (p less than 0.05) more effective than systemic intravenous injection against spontaneous ventricular tachycardia 1 day after coronary artery occlusion (13 dogs) and against electrically induced sustained ventricular tachycardia in the 3 to 12 day postocclusion period (9 dogs). Significantly lower doses of procainamide were used with retroinfusion as compared with systemic administration, that is, 19.6 +/- 8.8 versus 35 +/- 0 mg/kg body weight during spontaneous tachycardia and 13.4 +/- 4.1 versus 32.1 +/- 2 mg/kg during induced tachycardia (p less than 0.01). Retroinfusion of saline solution through the great cardiac vein had no effect on either type of tachycardia. Myocardial tissue procainamide levels measured in infarcted and ischemic zones of the left anterior ventricular wall were 9 to 100 times higher after great cardiac vein retroinfusion than after systemic injection. Great cardiac vein dye injection studies demonstrated a preferential distribution in left ventricular regions supplied by the occluded coronary artery. It is concluded that regional coronary venous procainamide retroinfusion in dogs with myocardial infarction is more effective than systemic intravenous injection against both spontaneous and inducible sustained ventricular tachycardia. The greater efficacy of great cardiac vein treatment appears to be primarily related to selectively increased delivery of procainamide to ischemic myocardial sites.

Efficacy of propafenone compared with quinidine in chronic ventricular arrhythmias

A double-blind, randomized study was designed to evaluate the efficacy of oral propafenone and oral quinidine in suppressing premature ventricular complexes (PVCs). Twenty-five men were studied for 3 weeks. Twelve were randomized to the quinidine group and 13 to the propafenone group. Small doses of the drugs were administered for 1 week (200 mg of quinidine every 6 hours or 300 mg of propafenone every 12 hours) and large doses were administered for another week (400 mg of quinidine every 6 hours or 300 mg of propafenone every 8 hours). Strict criteria were used to define responders to antiarrhythmic therapy. For more than 85% reduction in total PVCs per hour: During the low-dose week, 36% in the quinidine group and 50% in the propafenone group were responders (difference not significant [NS]), while during the high-dose week 33% and 64% were responders (NS). For more than 95% reduction of ventricular couplets per hour: During the low-dose week, 45% in each group were responders, while during the high-dose week, 56% and 60% were responders (NS). For 100% abolition of ventricular tachycardia (VT) beats per 24 hours: During the low-dose week, 60% in the quinidine group and 56% in the propafenone group were responders (NS); during the high-dose week 80% and 67% were responders (NS). There was no significant difference in the 2 groups in incidence of side effects. This study shows comparable efficacy and tolerance of propafenone and quinidine for the control of ventricular arrhythmias in ambulatory patients with diverse forms of heart diseases.

Concentration-dependent clearance of procainamide in normal subjects

Four normal volunteers each received two intravenous doses of PA. The mean low dose was 3.30 mg kg-1 (infused over 20 minutes) while the mean high dose was 12.5 mg kg-1 (infused over 60 minutes). Blood samples were collected for 12 hours and urine was collected for 48 hours after each dose. PA concentrations were determined by both HPLC and fluorescent immunoassay methods. The reported concentrations and pharmacokinetic parameters are from the HPLC data unless otherwise indicated. The mean peak serum PA concentrations resulting from the low and high doses were 3.18 and 9.07 micrograms ml-1, respectively. Total PA clearance averaged 763 ml min-1 and 577 ml min-1 while renal clearance averaged 360 ml min-1 and 318 ml min-1 after the low and high doses, respectively. Concentration-dependent decreases in nonrenal PA clearance ranged from 31 to 43 percent (p less than 0.05) in the four subjects. Total clearance decreases ranged from 4.7 to 36 per cent (p less than 0.05). Differences between doses in renal clearance, elimination rate constant, and volume of distribution were not statistically significant. This study demonstrates that the nonrenal and total clearances of PA are concentration-dependent in normal subjects at therapeutic plasma PA concentrations and suggests that the total clearance changes are of sufficient magnitude to be clinically important.

Ventricular arrhythmias in severe heart failure: incidence, significance, and effectiveness of antiarrhythmic therapy

Forty-three patients receiving maximal medical therapy for severe chronic heart failure from dilated cardiomyopathies (28 ischemic, 15 idiopathic) and ventricular premature beats (VPBs) on the 12-lead ECG had baseline 24-hour ambulatory ECG monitoring. Complex VPBs (multiform, repetitive--couplets, R on T phenomenon) and asymptomatic, nonsustained ventricular tachycardia were present in 38 patients (88%) and 22 patients (51%), respectively. Twenty-three patients (group I) were placed on long-term antiarrhythmic therapy (20 patients received procainamide and the remaining quinidine). Twenty patients (group II) did not receive antiarrhythmic therapy. At baseline, no significant differences between the two groups were noted for age, functional class, type of cardiomyopathy, medical therapy for heart failure, cardiothoracic ratio, radionuclide ejection fraction, or rate and complexity of the ventricular arrhythmias on the 24-hour ambulatory ECG tracings. At a mean follow-up period of 16 months (range 1 to 37), there were 16 deaths, 10 (62%) of which were sudden and unexpected. No significant differences in the incidence of sudden death and overall mortality were noted between the two groups. Among patients with nonsustained ventricular tachycardia, those who died suddenly had a lower mean left ventricular ejection fraction (0.15 +/- 0.01) when compared to the survivors (0.23 +/- 0.02; p less than 0.01). It is concluded that patients with severe heart failure have a high mortality from both sudden and nonsudden cardiac death, incidence of complex VPBs is very high, sudden death is more common when the left ventricular function is severely compromised, and apparently, therapeutic plasma levels of conventional antiarrhythmic drugs do not protect this group of patients from dying.

Efficacy of flecainide in the management of ventricular arrhythmias: comparative study with amiodarone

The effects on ventricular arrhythmias of a new class IA drug, flecainide, were compared with those of amiodarone in 10 patients with frequent, chronic, and stable ventricular ectopic beats (VEBs). The study consisted of an initial 1-week, placebo-controlled, baseline period followed by two 12-day, randomized, crossover, double-blind treatment periods with incremental dosage and 1 month of placebo between drug periods. Frequent VEBs, which were present in all 10 patients during both placebo control periods (30 or more VEBs/hour every hour, during 24-hour Holter monitoring), were markedly suppressed (reduction greater than 80%) in nine patients with both drugs (p less than 0.01). There was almost total abolition of the VEBs in six patients with flecainide, and the satisfactory results with a minimal dose in three demonstrate its fast onset of action. Side effects from either agent were infrequent and no discontinuation was necessary. We conclude from our study that flecainide is a highly effective antiarrhythmic agent.

The utility of aprindine blood levels in the management of ventricular arrhythmias

Sixty-four patients with a history of ventricular tachycardia and ventricular fibrillation refractory to conventional therapy received aprindine to abolish recurrent episodes of symptomatic ventricular tachycardia. Fifty-six patients became asymptomatic and were followed up for a mean period of 23 months. Aprindine dose was adjusted to minimize adverse reactions but still control arrhythmia. Survival analysis was performed for the group with aprindine levels greater than 1.5 micrograms/ml and the group with levels of 1.5 micrograms/ml or less. At the end of the study, 65% of the patients with a high level were alive and asymptomatic as compared with only 35% of the patients with a low level (p less than 0.036). In patients at risk of recurrent sudden cardiac death, high aprindine levels maintained after abolition of symptomatic ventricular tachycardia were associated with improved survival.

Comparative electrophysiologic effects of intravenous and oral procainamide in patients with sustained ventricular arrhythmias

Thirty-three patients with sustained ventricular arrhythmias underwent electrophysiologic testing after intravenous and again after oral procainamide administration. Two groups were identified: group 1 included 15 patients with concordant serum procainamide concentrations with less than a 3 micrograms/ml difference after intravenous (mean 8.6 +/- 2.7) and oral (mean 8.8 +/- 2.7) procainamide administration, with mean N-acetylprocainamide concentrations of 1.0 +/- 0.6 and 6.2 +/- 2.8 micrograms/ml, respectively. Group 2 included 18 patients with discordant serum procainamide concentrations after intravenous (mean 9.5 +/- 5.9 micrograms/ml) and oral (mean 14.1 +/- 5.2 micrograms/ml) procainamide, with mean N-acetylprocainamide concentrations of 0.9 +/- 0.5 and 10.7 +/- 5.7 micrograms/ml, respectively. In group 1, response to programmed stimulation was the same after intravenous and oral procainamide administration, with no inducible ventricular arrhythmia in 5 of 15 patients. In group 2, 3 of 18 patients had no inducible arrhythmia after intravenous compared with 7 of 18 patients after oral procainamide administration. There was a different response to programmed stimulation after oral compared with intravenous procainamide in 6 of 18 patients in group 2 but in none of 15 patients in group 1 (p = 0.02). The effective procainamide concentration was greater than the ineffective concentration in five of the six patients with a discordant response, and the effective route of administration was oral in five of the six patients. The change in ventricular refractoriness in group 1 was similar after intravenous (28 +/- 23 ms) and oral (29 +/- 19 ms) procainamide, whereas in group 2, refractoriness was increased more after oral (33 +/- 21 ms) than intravenous (20 +/- 17 ms) procainamide administration and paralleled the difference in procainamide concentration.(ABSTRACT TRUNCATED AT 250 WORDS)

Indomethacin sustained-release?

Recently, many new formulations of older drugs have been marketed as sustained-release preparations. Only some of these compounds have scientific rationale supporting their development. At least two inherent properties of a drug are desirable in considering its reformulation into a sustained-release entity. On of these properties is the demonstration of a concentration/response relationship together with a short plasma elimination half-life and inactive or uncharacterized activity of any generated metabolites. The second property is the production of transient side effects associated with dissolution and/or peak concentrations. When neither of these conditions is satisfied, then a sustained-release preparation may offer no advantages over the conventional formulation. The literature on indomethacin was examined with respect to the above conditions and it was concluded that its marketing as a sustained-release preparation is not justified and that investigations have failed to demonstrate clinical advantages of this new formulation.

Procainamide: clinical pharmacology and efficacy against ventricular arrhythmias

Procainamide (PA) has been a mainstay of treatment against acute and chronic supraventricular and ventricular arrhythmias for more than 30 years. PA's clinical pharmacology has been studied extensively and its bioavailability (75-95%); volume of distribution (1.5-2.5 liters per kg), plasma protein-binding (15-25%), half-time for elimination (3-7 hours), and metabolism are known. PA's efficacy against acute ventricular arrhythmias and chronic stable VPDs is associated with plasma drug concentrations of 4 to 10 micrograms per ml; but much higher plasma concentrations may be required against sustained ventricular arrhythmias. From 30 to 60% of a PA dose is excreted as the metabolite, N-acetylprocainamide (NAPA), and PA's metabolism is determined genetically (fast or slow acetylation phenotype). Studies in patients with VPDs indicate that NAPA is also antiarrhythmic, although the contribution of NAPA to the antiarrhythmic effect after PA is not known. Studies in patients with the systemic lupus-like syndrome from PA show that NAPA is not associated with this. Investigations comparing efficacy and adverse effects of PA with those of new antiarrhythmic agents available for clinical trials are indicated in the future.