A new preclinical biomarker for risk of Torsades de Pointes: drug-induced reduction of the cardiac electromechanical window

Evaluation of new therapeutic agents for their potential to cause QT interval prolongation and drug-induced ventricular arrhythmia, like Torsades de Pointes (TdP), is a critical activity during drug development. The QT interval has been used as a surrogate biomarker to assess ventricular repolarization effects caused by drug-induced blockade of cardiac repolarizing currents, mainly I_Kr, but is imperfect in predicting proarrhythmia. Evidence suggests that left ventricular mechanical dysfunction may also contribute to ventricular arrhythmias; thus, electrical and mechanical alterations may have a role in drug-induced TdP. The electromechanical window (EMw) represents the time difference between the end of electrical systole (i.e. the QT interval) and the completion of ventricular relaxation (i.e. the QLVP_end interval), and appears to be a new potential biomarker for TdP risk. A reduction in the EMw (to negative values) has now been shown to be associated with the onset of TdP in an anaesthetized dog model of long QT1 syndrome. Therefore, the EMw represents a novel indicator of TdP risk that may add predictive value beyond assay of drug-induced QT interval prolongation.

LINKED ARTICLE

This article is a commentary on van der Linde et al., pp. 1444–1454 of this issue. To view this paper visit http://dx.doi.org/10.1111/j.1476-5381.2010.00934.x     

Prolongation in QT interval is not predictive of Ca2+-dependent arrhythmias: implications for drug safety

Background: Voltage-gated ion channels are the main providers of drug-induced delayed repolarization and, therefore, first line targets in cardiac safety assessments. Objectives/methods: We review mechanisms of drug-induced ventricular arrhythmias that may be associated with sudden cardiac death. We focus on Ca²⁺-dependent mechanisms with drug safety concerns. Results: Early afterdepolarizations occur during abnormally prolonged action potential repolarization. QT interval measurement is commonly used to assess the proarrhythmic risk of a drug. However, delayed afterdepolarizations are triggered by intracellular Ca²⁺ overload and/or abnormal spontaneous openings of ryanodine receptors in diastole. A drug promoting alterations of Ca²⁺ handling may be pro-arrhythmogenic without QT interval change at rest. Conclusion: Ca²⁺-dependent arrhythmia should be investigation matter in drug safety evaluation.     

QT-interval prolongation by non-cardiac drugs: lessons to be learned from recent experience

Background: Evidence has accrued that several non-cardiac drugs may prolong cardiac repolarisation (hence, the QT interval of the surface electrocardiogram) to such a degree that potentially life-threatening ventricular arrhythmias (e.g. torsades de pointes) may occur, especially in case of overdosage or pharmacokinetic interactions. Discussion: This has fostered discussion on the molecular mechanisms underlying the class-III anti-arrhythmic effect shared by apparently disparate classes of drugs, on the clinical relevance of this side effect and on possible guidelines to be followed by drug companies, ethics committees and regulatory agencies in the risk–benefit assessment of new and licensed drugs. This review provides an update on the different classes of non-cardiac drugs reported to prolong the QT interval (e.g. histamine H₁-receptor antagonists, antipsychotics, antidepressants and macrolides), on the possible underlying molecular mechanisms and on the clinical relevance of the QT prolonging effect. Identification and widespread knowledge of risk factors that may precipitate prolongation of the QT interval into life-threatening arrhythmias becomes an important issue. Risk factors include congenital long QT syndrome, clinically significant bradycardia or heart disease, electrolyte imbalance (especially hypokalaemia, hypomagnesaemia), impaired hepatic/renal function and concomitant treatment with other drugs with known potential for pharmacokinetic/pharmacodynamic interactions (e.g. azole antifungals, macrolide antibacterials and class-I or -III anti-arrhythmic agents). Future perspectives for drug research and development are also briefly outlined. Received: 4 October 1999 / Accepted in revised form: 13 January 2000     

Understanding drug-induced torsades de pointes: a genetic stance

Drugs may produce a variety of arrhythmias, but drug-induced QT prolongation and the risk of the polymorphic ventricular tachycardia torsades de pointes (drug-induced long QT syndrome) has garnered the most attention. The wide array of drugs with potential for QT prolongation, the correspondingly large number of patients exposed to such drugs, the difficulty in predicting an individual's risk, and the potentially fatal outcome, make drug-induced long QT syndrome an important public health problem for clinicians, researchers, drug development programs, and regulatory agencies. This review focuses on the genetic risk factors and mechanisms underlying QT prolongation and proarrhythmia. The post-genomic era hints at an improved understanding (and prediction) of how the gene-environment interaction produces this particular adverse drug response.     

Drug-induced torsade de pointes

Three patients who developed torsade de pointes associated with antiarrhythmic or psychotropic drugs are described, and the electrocardiographic characteristics, clinical presentation, predisposing factors, and management of this form of ventricular tachycardia are reviewed. The first patient was a 56-year-old schizophrenic man receiving thioridazine hydrochloride, trifluoperazine hydrochloride, and benztropine mesylate who was admitted to a hospital after a syncopal episode. Subsequently, the patient experienced several episodes of ventricular tachycardia combined with multifocal premature ventricular contractions (PVCs) and torsade de pointes; the arrhythmias were attributed to antipsychotic therapy. The second patient was a 69-year-old man who experienced ventricular tachycardia that progressed to ventricular fibrillation 41 days after surgery. Quinidine sulfate probably induced the ventricular tachycardia, which was identified as torsade de pointes. The third patient was a 71-year-old man admitted to the hospital for treatment of refractory ventricular arrhythmias. Previous drug therapy with quinidine sulfate and procainamide hydrochloride had been associated with torsade de pointes. Despite unsuccessful treatment of ventricular ectopy, the patient was discharged on maintenance therapy with pindolol, topical nitrates, and phenytoin. No additional episodes of torsade de pointes have been observed. Torsade de pointes is characterized by polymorphous electrocardiographic appearance and delayed repolarization (prolonged QT interval). It may occur in association with a number of disease states and also as a complication of treatment with therapeutic doses of drugs that affect repolarization (quinidine, disopyramide, procainamide, and phenothiazines). Clinical outcomes range from asymptomatic, self-terminating arrhythmias to ventricular fibrillation resulting in cardiac arrest. The definitive emergency therapy for torsade de pointes is overdrive pacing; cautious isoproterenol administration can also be used. Lidocaine and bretylium are often ineffective in treating this form of ventricular tachycardia. Potassium and magnesium repletion appear to be essential in abolishing drug-induced torsade de pointes. Drug-induced torsade de pointes is best prevented by avoiding agents known to induce arrhythmias in patients with a pre-existing prolonged QT interval. Periodic serum electrolyte assessment is warranted, and new drugs that prolong the QT interval should be considered potential causative agents of torsade de pointes.     

抗新型冠状病毒药物致QT间期延长的文献复习及药学监护

本文对新型冠状病毒肺炎患者临床用药方案涉及的抗病毒药物致QT间期延长的文献报道情况进行复习。根据目前文献复习结果可知,洛匹那韦/利托那韦和磷酸氯喹存在引起QT间期延长进而引发尖端扭转型室速的潜在风险。在新型冠状病毒肺炎患者中使用此类药物需关注由此带来的用药风险,熟悉临床上常用的可引起QT间期延长的药物,提高识别患者QT间期延长的易感因素和药物相互作用的能力,重视心电图、电解质管理来预防临床潜在的药物致急性心律失常事件,以降低新型冠状病毒肺炎患者的药物不良反应,避免药源性损害。     

Cardiotoxic effects of antihistamines: from basics to clinics (...and back)

Drug-induced arrhythmias, particularly those caused by a prolonged QT interval, have become a critical safety issue for compound selection during development by pharmaceutical companies and for health care regulators. The last two decades have witnessed enormous progress in the definition of the clinical conditions that facilitate the occurrence of such serious adverse effects, of its molecular basis, and in the preclinical strategies aimed at early identification of the cardiotoxic liability of compounds undergoing investigation or already used in the clinic. Moreover, despite the fact that acquired factors play an obvious role in drug-induced arrhythmias, it has become evident that the disease is often manifested upon the interaction of strong environmental stressors with specific genetic determinants of the affected individuals; in that sense, few examples can illustrate the existing interaction between acquired and genetic factors in disease manifestation better than drug-induced arrhythmogenesis. Progress in this field has been mainly driven by a strong interaction among various disciplines, including medicinal chemistry, pharmacology, electrophysiology, molecular genetics, and clinical cardiology; such an interdisciplinary approach has often generated unexpected discoveries of great clinical value, allowing clinicians to drive drug selection toward compounds of proven efficacy and safety. Historically, studies on antihistamines have paved the way for much of our current understanding of the mechanisms and problems associated with QT prolongation and drug-induced arrhythmogenesis; therefore, in this perspective, we will attempt to summarize how basic research studies have helped the interpretation of clinically relevant phenomena (from basics to clinics...) and how this information has prompted new emphasis in preclinical studies aimed at predicting the cardiotoxic potential of compounds (...and back). The current availability of several strategies provided with great predictive potential, together with an increased awareness of physicians, pharmaceutical industries, and health care regulators to this potentially serious cardiovascular side effect, has significantly decreased the risk associated with drug-induced arrhythmias caused by drugs newly introduced into the market; nevertheless, given the large number of cases of QT prolongation still occurring during treatment with a wide variety of congeners, it seems appropriate to review the issue of the cardiotoxic actions of antihistamines, as a better comprehension of the underlying mechanisms and risk factors is likely to contribute to the improvement of the risk/benefit ratio for pharmacological treatment in several therapeutic areas.     

Sudden cardiac death secondary to antidepressant and antipsychotic drugs

A number of antipsychotic and antidepressant drugs are known to increase the risk of ventricular arrhythmias and sudden cardiac death. Based largely on a concern over QT prolongation and the development of life-threatening arrhythmias, a number of antipsychotic drugs have been temporarily or permanently withdrawn from the market or their use restricted. Some antidepressants and antipsychotics have been linked to QT prolongation and the development of Torsade de pointes arrhythmias, whereas others have been associated with a Brugada syndrome phenotype and the development of polymorphic ventricular arrhythmias. This review examines the mechanisms and predisposing factors underlying the development of cardiac arrhythmias, and sudden cardiac death, associated with antidepressant and antipsychotic drugs in clinical use.     

Assessing QT interval prolongation and its associated risks with antipsychotics

Several antipsychotics are associated with the ventricular tachycardia torsade de pointes (TdP), which may lead to sudden cardiac death (SCD), because of their inhibition of the cardiac delayed potassium rectifier channel. This inhibition extends the repolarization process of the ventricles of the heart, illustrated as a prolongation of the QT interval on a surface ECG. SCD in individuals receiving antipsychotics has an incidence of approximately 15 cases per 10,000 years of drug exposure but the exact association with TdP remains unknown because the diagnosis of TdP is uncertain. Most patients manifesting antipsychotic-associated TdP and subsequently SCD have well established risk factors for SCD, i.e. older age, female gender, hypokalaemia and cardiovascular disease. QT interval prolongation is the most widely used surrogate marker for assessing the risk of TdP but it is considered somewhat imprecise, partly because QT interval changes are subject to measurement error. In particular, drug-induced T-wave changes (e.g. flattening of the T-wave) may complicate the measurement of the QT interval. Furthermore, the QT interval depends on the heart rate and a corrected QT (QTc) interval is often used to compensate for this. Several correction formulas have been suggested, with Bazett's formula the most widely used. However, Bazett's formula overcorrects at a heart rate above 80 beats per minute and, therefore, Fridericia's formula is considered more appropriate to use in these cases. Several other surrogate markers for TdP have been developed but none of them is clinically implemented yet and QT interval prolongation is still considered the most valid surrogate marker. Although automated QT interval determination may offer some assistance, QT interval determination is best performed by a cardiologist skilled in its measurement. A QT interval >500?ms markedly increases the risk for TdP and SCD, and should lead to discontinuation of the offending drug and, if present, correction of underlying electrolyte disturbances, particularly serum potassium and magnesium derangements. Before prescribing antipsychotics that may increase the QTc interval, the clinician should ask about family and personal history of SCD, presyncope, syncope and cardiac arrhythmias, and recommend cardiology consultation if history is positive.     

Is gender a risk factor for adverse drug reactions? The example of drug-induced long QT syndrome.

Drug-induced torsade de pointes is a rare life-threatening adverse drug reaction (ADR) which is strongly influenced by gender. Drugs that prolong cardiac repolarisation include antiarrhythmics, gastrokinetics, antipsychotics, antihistamines and antibacterials. Such drugs share the potential to block cardiac voltage-gated potassium channels, particularly the rapid component (I(Kr)) of the delayed rectifier potassium current (I(K)). By doing so, such drugs usually, but not always, prolong the QT interval. Even if the electrocardiographic signs are subdued, the underlying blockade of I(Kr) current may precipitate the occurrence of arrhythmia. Women are perceived to be more prone to ADRs than men. Such a propensity may result from gender-associated differences in drug exposure, in the number of drugs prescribed (polypharmacy), in drug pharmacology, as well as from possible differences in the way the adverse event is perceived. A prolonged QT interval on the electrocardiogram (time that elapses from the onset of the cardiac ventricular depolarisation to the completion of its repolarisation) is associated with the occurrence of torsade de pointes and related ventricular arrhythmias. The QT interval is influenced by heart rate, autonomic nervous system, electrolyte disturbances and above all, drugs that block potassium channels. Two-thirds of the cases of drug-induced torsade de pointes occur in women. Therefore, this adverse effect represents a perfect example of gender differences impairing women's health. Clinical and experimental studies show that female gender is associated with a longer corrected QT interval at baseline and a greater response to drugs that block I(Kr), both of which facilitate the emergence of arrhythmia. This results most likely from a specific regulation of ionic channel expression (potassium, calcium, etc) by sex steroids, even though nongenomic effects may play a role as well. Estrogens facilitate bradycardia-induced prolongation of the QT interval and the emergence of arrhythmia whereas androgens shorten the QT interval and blunt the QT response to drugs. Hence, underlying genetic defects of potassium channels that may be asymptomatic in normal conditions, may precipitate drug-induced arrhythmia in women more frequently than in men. Even in the presence of a drug that mildly blocks I(Kr) and seldom prolongs the QT interval, women are still more prone to drug-induced torsade de pointes, due to their reduced cardiac 'repolarisation reserve'. This is an important aspect of I(Kr) blockade to be aware of during the development of new drugs.     

药物致Q-T间期延长的文献分析

近年来,临床实践有许多药物都会导致Q-T间期延长甚至尖端扭转型室性心律失常（TdP）。本文通过对1979年-2013年国内医药期刊公开报道的药物致Q-T间期延长的个案进行统计和分析,总结了56个病例的一般情况、引起Q-T间期延长的药物、发生时间及转归等,致Q-T间期延长药物中排在前三位的分别为抗心律失常药、抗微生物药、抗组胺药。大部分患者在用药后一个月内出现,停药及对症治疗后好转。临床医师应正确地认识药物致Q-T间期延长发生机制和易感因素,才能保证临床安全有效地使用药物。     

Safety of droperidol in behavioural emergencies

By the year 2000, droperidol had become a standard drug for the treatment of behavioural emergencies in both psychiatric and medical settings. In 2001, the US FDA issued a ‘black box’ warning, citing cases of QT prolongation and/or torsades de pointes. As a result, the use of droperidol has been sharply circumscribed. The authors will review the literature on antipsychotic medications in general, focusing on droperidol in particular, with regard to QT interval prolongation, dysrhythmia, and sudden death. In addition, the mechanism of drug-induced QT interval prolongation will be discussed. The authors will then review their extensive experience with droperidol. The authors conclude that, while in theory droperidol may prolong the QT interval to an extent similar to thioridazine, its long history of clinical use has shown no pattern of sudden deaths analogous to those that provoked the FDA warning. Although the numbers presented by the FDA initially appear alarming, after further evaluation it is clear that more definitive studies should have been carried out. Droperidol is safe, extremely effective, and now underused as a treatment for severely agitated or violent patients.     

Calculation of QT shift in non clinical safety pharmacology studies

IntroductionDrug-induced QT interval prolongation is a major concern in new drug candidate development. This study presents a method of assessment of drug-induced QT interval prolongation without need for QT correction in conscious Beagle dogs and Cynomolgus monkeys monitored by telemetry. Accuracy and reliability are analysed by comparison with a reference QT correction method (Holzgrefe) from experiments performed with reference substances terfenadine, thioridazine and sotalol.MethodsThe QT shift method principle is assessment of any drug-induced QT interval shift directly from the individual QT/RR relationship. The individual QT/RR relationship is built from a treatment-free 24-hour recording period. QT and RR intervals are determined from a beat-to-beat analysis. A probabilistic method is used to define the individual QT/RR relationships. Checks were performed to compare results obtained with the QT shift method and the QT correction methods. The robustness of the QT shift method was tested under various conditions of drug-induced heart rate change (i.e. normal, bradycardia and tachycardia).ResultsThe extent of agreement with the used reference QT correction method, Holzgrefe formula, was excellent (3–4 ms) in both animal species under the various drug induced effects on heart rate. The statistical sensitivity threshold for detection of QT prolongation according to a standard safety pharmacology study design was 7–8 ms.DiscussionWhen combined with the probabilistic determination of individual QT/RR relationships, this simple method provides a direct assessment of a drug-induced effect on QT interval, without any curve fitting or application of correction formula. Despite noticeably different shapes in QT/RR relationships, the QT shift method is applicable to both Beagle dogs and Cynomolgus monkeys. It is likely that the QT shift method will be particularly helpful in problematic cases, enabling detection of drug-induced prolongation of less than 10 ms.     

Modulation of the late sodium current by ATX-II and ranolazine affects the reverse use-dependence and proarrhythmic liability of IKr blockade

BACKGROUND AND PURPOSE

Drug-induced torsades de pointes (TdP) often occurs during bradycardia due to reverse use-dependence. We tested the hypothesis that inhibition or enhancement of late sodium current (I_Na,L) could modulate the drug-induced reverse use-dependence in QT and T_p-e (an index of dispersion of repolarization), and therefore the liability for TdP.

EXPERIMENTAL APPROACH

Arterially perfused rabbit left ventricular wedge preparations were used. Action potentials from the endocardium were recorded simultaneously with a transmural ECG. The effects of Anemonia sulcata toxin (ATX-II) (an I_Na,L enhancer), d,l-sotalol, clarithromycin and ranolazine (an I_Na,L blocker) on rate-dependent changes in QT, T_p-e and proarrhythmic events were tested, either alone or in combination. Rate-dependent QT and T_p-e slopes and TdP score (a combined index of TdP liability) were calculated at control and during drug infusion.

KEY RESULTS

ATX-II (30 nM) and sotalol (300 µM) caused a marked increase in QT and T_p-e intervals, steeper QT-basic cycle length (BCL) and T_p-e-BCL slopes (i.e. reverse use-dependence), and TdP. Addition of ranolazine (15 µM) to ATX-II or sotalol significantly attenuated QT-BCL, T_p-e-BCL slopes and the increased TdP scores. In contrast, clarithromycin (100 µM) moderately prolonged QT and T_p-e without causing R-on-T extrasystole or TdP, but addition of ATX-II (1 nM) to clarithromycin markedly amplified the QT-BCL and T_p-e-BCL slopes and further increased TdP score.

CONCLUSION AND IMPLICATIONS

Modulation of I_Na,L altered drug-induced reverse use-dependence related to QT as well as T_p-e, indicating that inhibition of I_Na,L can markedly reduce the TdP liability of agents that prolong QT intervals.     

QTc interval prolongation and antipsychotic drug treatments: focus on sertindole

Since the 1960s, physicians have been aware of electrocardiographic (ECG) abnormalities and cases of sudden death associated with the use of antipsychotic drugs in patients with schizophrenia. Explanations for such deaths have traditionally focused on drug-induced prolongation of the QT interval leading to the development of life-threatening ventricular arrhythmias such as torsade de pointes (TdP). It is now apparent that most conventional and atypical antipsychotics can cause dose-related prolongation of the corrected QT interval (QTc), although there are important differences in the potency of individual agents. This review discusses potential mechanisms underlying QTc prolongation and arrhythmogenesis and examines the evidence for a relationship between antipsychotic drugs and prolongation of the QTc interval. New electrophysiological and epidemiological data are presented which suggest there may not be a clear-cut cause-effect relationship between QTc prolongation and the development of ventricular tachyarrhythmias for all atypical antipsychotics. For at least one of these agents (sertindole), counterbalancing mechanisms may act to reduce the risk of proarrhythmic activity arising as a result of QTc prolongation.     

Pharmacogenetics of cardiac K(+) channels

A number of commonly prescribed drugs belonging to various therapeutic classes (antiarrhythmic, antibiotic, antifungal, antihistamine, antipsychotic, prokinetic drugs…) possess, in common, the adverse property to prolong cardiac repolarization [prolonged QT interval duration on surface electrocardiogram (ECG)], exposing patients to a risk of torsade-de-pointes arrhythmias, syncope, and sudden death. Arrhythmias related to drug-induced QT prolongation do not occur in every patient treated with these drugs but most likely occur in a subset of susceptible patients. These patients have a high risk of recurrence of arrhythmias upon exposure to any of the other drugs that broaden the QT interval. It is currently suspected (though not yet proven) that susceptible individuals carry a silent mutation in one of the genes responsible for the congenital long QT syndrome. Indeed, it appears more and more clear that a large proportion of congenital long QT syndrome gene carriers, have a normal QT interval and a normal phenotype and therefore, remain undiagnosed. Therefore, a much larger than previously thought proportion of the general population may be affected by asymptomatic mutations in cardiac ion channel encoding genes. No routine technology is currently available in identifying these patients preventively.     

Drug induced shortening of the QT/QTc interval: An emerging safety issue warranting further modelling and evaluation in drug research and development?

IntroductionA session dedicated to the issue of drug-induced QT and/or QTc interval (QT/QTc) shortening of the electrocardiogram (ECG) was held at the 2007 Safety Pharmacology Society (SPS) meeting in Edinburgh.MethodsThe session included a presentation on the results of a cross company survey on QT/QTc-shortening, a podium debate with speakers arguing “for” and “against” QT/QTc shortening being a safety issue and a panel discussion with the audience.ResultsCompared to QT/QTc prolongation, relatively little is known about the relevance to safety of drug-induced QT/QTc shortening. As with QT/QTc prolongation, there are genetic syndromes and pharmaceutical agents which cause shortening of QT/QTc. The potential safety issue of QT/QTc shortening and its suitability as a biomarker of drug-induced cardiac arrhythmias, are unclear, however, the type of arrhythmia associated with prolongation and shortening are thought to differ. Prolongation is associated with torsades de pointes, whereas, shortening of QT/QTc is proposed to be associated with the more severe arrhythmia, ventricular fibrillation (VF). The industry-wide survey (53 total responses representing 45 different companies) indicates that the number of compounds that induce QT/QTc shortening has increased over the past 5 years with 51% of responses reporting QT/QTc shortening in pre-clinical studies and 22% reporting a corresponding clinical experience. The reason for the increase is not clear but there is a clear business impact with 13% (7/56) of these compounds being discontinued in the pre-clinical phase due to QT/QTc shortening. The majority of companies with clinical experience of QT/QTc shortening have engaged with the regulatory agencies and these experiences will be valuable in shaping how the pharmaceutical industry and the agencies view drug-induced QT/QTc shortening in the future.DiscussionCurrently it is not clear how much shortening of QT/QTc is required before it might be considered a safety issue and indeed, whether QT/QTc shortening is a suitable biomarker for cardiac arrhythmias. It is clear, however, that with our current understanding, compounds which shorten QT/QTc will attract close regulatory scrutiny and carry a business risk. The need to better understand this potential cardiac safety issue points to further research including; model development to determine the mechanism(s) of action of drug-induced QT/QTc shortening and the translation between the non-clinical and clinical situation.     

A novel approach to data processing of the QT interval response in the conscious telemetered beagle dog

INTRODUCTION: Drug-induced QT interval prolongation may lead to ventricular arrhythmias. The aim of the study was to optimize QT interval data processing to quantify drug-induced QT interval prolongation in the telemetry instrumented conscious dog model. METHODS: The test substances cisapride, dofetilide, haloperidol, and terfenadine and corresponding vehicles were given to male and female beagle dogs during two consecutive 90-min intravenous infusions. Cardiovascular parameters were recorded for 24 h and exposure to the drugs was measured. The delayed response in the QT interval after an abrupt change in heart rate was investigated. Eight mathematical models to describe the QT interval-heart rate relationship were compared and different sets of covariates were used to quantify the drug-induced effect on the QT interval. RESULTS: After an abrupt decrease in heart rate, a 75% adaptation of the QT interval was reached after 54+/-9 s. A linear model was preferred to correct the drug-induced effect on the QT interval for heart rate, vehicle effect, serial correlation, plasma concentration and time of day. All test substances significantly prolonged the QT interval. DISCUSSION: To optimize the processing of QT interval data, the delay in QT interval response after an abrupt change in heart rate should be considered. The QT interval-heart rate relationship and vehicle response were individual-specific and corrections were therefore made individually. When estimating the drug-induced effect on the QT interval it is considered advantageous to use plasma concentration as a covariate, as well as adjusting for vehicle effect and serial correlation in measurements. The conscious dog model detected significant increases in the QT interval for all test substances investigated.     

Inherited cardiac arrhythmia syndromes: What have they taught us about arrhythmias and anti‐arrhythmic therapy?

1. In recent years, the identification of the gene defects in a vast array of monogenic disorders has revolutionized our understanding of the basic mechanisms underlying numerous disease processes. 2. Mutations in cardiac ion channels have been identified as the basis of a wide range of inherited arrhythmia syndromes, including the congenital long QT syndromes, Brugada syndrome, Lenegre syndrome, Andersen's disease and familial atrial fibrillation. 3. Identification of mutations in the human-ether-a-go-go-related gene (HERG) K(+) channel as the molecular basis of congenital long QT syndrome type 2 also led to the discovery that HERG is the molecular target for the vast majority of drugs (both cardiac and non-cardiac) that cause drug-induced arrhythmias. This has had profound implications not only for the development of anti-arrhythmic agents, but also for drug development in general. 4. The sequencing of the human genome in a sense represents the pinnacle of the reductionist era of molecular medicine. The great challenge now is to re-integrate the information gathered during the 'reductionist era' to provide a better understanding of the intact organism. Computer modelling is likely to be a key component of that re-integration process.     

Pharmacodynamic analysis of the electrocardiographic interaction between disopyramide and erythromycin in rats

Disopyramide (DP) is known to induce QT prolongation and Torsades de Pointes (TdP) when administered concomitantly with erythromycin (EM). To define and evaluate quantitatively the arrhyth‐mogenic risk of the concomitant administration of DP and EM, we investigated the influence of EM on the pharmacokinetics and pharmacodynamics of DP in rats. The time profiles of change in QT interval and plasma concentration of each drug were evaluated during and after constant intravenous infusion of DP (6.0 or 15.0 mg/kg/h), EM (4.0 or 8.0 mg/kg/h), and coadministration of DP and EM (DP 6.0 mg/kg/h plus EM 4.0 mg/kg/h). Each agent induced QT prolongation at plasma concentrations within the therapeutic range in humans. DP‐induced QT prolongation was proportional to its plasma concentration. In the case of EM, the E_max model with an “effect compartment” could explain the relationship between plasma EM concentrations and changes in QT interval. Although coadministration of EM with DP gave enhanced QT prolongation compared to dosing with DP alone, EM did not affect the pharmacokinetics of DP. In conclusion, it was shown that a pharmacodynamic interaction contributes to the electrocardiographic adverse reaction (i.e., QT prolongation) induced by coadmin‐istration of DP and EM in rats.