QT PRODACT: Evaluation of the Potential of Compounds to Cause QT Interval Prolongation by Action Potential Assays Using Guinea-Pig Papillary Muscles

Comprehensive in vitro cardiac safety assessment using human stem cell technology: Overview of CSAHi HEART initiative

Recent increasing evidence suggests that the currently-used platforms in vitro I_Kr and APD, and/or in vivo QT assays are not fully predictive for TdP, and do not address potential arrhythmia (VT and/or VF) induced by diverse mechanisms of action. In addition, other cardiac safety liabilities such as functional dysfunction of excitation-contraction coupling (contractility) and structural damage (morphological damage to cardiomyocytes) are also major causes of drug attrition, but current in vitro assays do not cover all these liabilities. We organized the Consortium for Safety Assessment using Human iPS cells (CSAHi; http://csahi.org/en/), based on the Japan Pharmaceutical Manufacturers Association (JPMA), to verify the application of human iPS/ES cell-derived cardiomyocytes in drug safety evaluation. The main goal of the CSAHi HEART team has been to propose comprehensive screening strategies to predict a diverse range of cardiotoxicities by using recently introduced platforms (multi-electrode array (MEA), patch clamp, cellular impedance, motion field imaging [MFI], and Ca transient systems) while identifying the strengths and weaknesses of each. Our study shows that hiPS-CMs used in these platforms have pharmacological responses more relevant to humans in comparison with existent hERG, APD or Langendorff (MAPD/contraction) assays, and not only MEA but also other methods such as impedance, MFI, and Ca transient systems would offer paradigm changes of platforms for predicting drug-induced QT risk and/or arrhythmia or contractile dysfunctions. Furthermore, we propose a potential multi-parametric platform in which field potential (MEA)-Ca transient-contraction (MFI) could be evaluated simultaneously as an ideal novel platform for predicting a diversity of cardiac toxicities, namely whole effects on the excitation-contraction cascade.

Intravenous anti-influenza drug oseltamivir will not induce torsade de pointes: Evidences from proarrhythmia model and action-potential assay

We evaluated proarrhythmic risk of intravenous oseltamivir with chronic atrioventricular block canine model (n = 4) and action-potential assay on guinea-pig right ventricle (n = 5). Oseltamivir in doses of 3-30 mg/kg, i.v. did not induce torsade de pointes in the canine model, whereas that in concentrations of 30-300 μM decreased maximum rate of phase 0 depolarization, shortened action potential duration at 30%, 60% and 90% repolarization levels, but prolonged difference in action-potential duration between 30% and 90% repolarization levels in a concentration-related manner. These results indicate that oseltamivir will not induce torsade de pointes clinically, since it inhibits both inward and outward currents.

Predicting drug-induced QT prolongation and torsades de pointes: a review of preclinical endpoint measures

Compound-induced prolongation of the cardiac QT interval is a major concern in drug development and this unit discusses approaches that can predict QT effects prior to undertaking clinical trials. The majority of compounds that prolong the QT interval block the cardiac rapid delayed rectifier potassium current, IKr (hERG). Described in this overview are different ways to measure hERG, from recent advances in automated electrophysiology to the quantification of channel protein trafficking and binding. The contribution of other cardiac ion channels to hERG data interpretation is also discussed. In addition, endpoint measures of the integrated activity of cardiac ion channels at the single-cell, tissue, and whole-animal level, including for example the well-established action potential to the more recent beat-to-beat variability, transmural dispersion of repolarization, and field potential duration, are described in the context of their ability to predict QT prolongation and torsadogenicity in humans.

Electrophysiological characterization of cardiomyocytes derived from human induced pluripotent stem cells

Cardiomyocytes derived from human induced pluripotent stem cells (hiPS-CMs) hold great promise for development of in vitro research tools to assess cardiotoxicity, including QT prolongation. In the present study, we aimed to clarify the electrophysiological/pharmacological characteristics of hiPS-CMs using the patch-clamp technique. The hiPS cells were differentiated into beating cardiomyocytes by the embryoid body method. The expression of genes related to cardiac ion channels and differentiation markers in cardiomyocytes were detected by RT-PCR. Whole-cell patch-clamp recordings were performed using single hiPS-CMs dispersed from beating colonies. We confirmed voltage-dependence of major cardiac ion currents (I(Na), I(Ca), I(Kr), and I(Ks)) and pharmacological responses to ion-channel blockers. Action potential duration (APD) was prolonged by both I(Kr)/hERG and I(Ks) blockers, whereas it was shortened by an I(Ca) blocker, indicating that these ion current components contribute to action potential generation in hiPS-CMs. As for multiple ion channel blockers, terfenadine prolonged APD, but verapamil did not, results which were identical to clinically relevant pharmacological responses. These data suggest that patch-clamp assay using hiPS-CMs could be an accurate method of predicting the human cardiac responses to drug candidates. This study would be helpful in establishing an electrophysiological assay to assess the risk of drug-induced arrhythmia using hiPS-CMs.

Evaluation of ventricular arrhythmias in early clinical pharmacology trials and potential consequences for later development

This white paper, prepared by members of the Cardiac Safety Research Consortium, discusses several important issues regarding the evaluation of ventricular arrhythmias in early clinical pharmacology trials and their potential consequences for later clinical drug development. Ventricular arrhythmias are infrequent but potentially important medical events whose occurrence in early clinical pharmacology trials can dramatically increase safety concerns. Given the increasing concern with all potential safety signals and the resultant more extensive electrocardiographic monitoring of subjects participating in early phase trials, an important question must be addressed: Are relatively more frequent observations of ventricular arrhythmias related simply to more extensive monitoring, or are they genuinely related to the drug under development? The discussions in this paper provide current thinking and suggestions for addressing this question.

Torsades de pointes liability inter-model comparisons: the experience of the QT PRODACT initiative

Safety pharmacologists from the Japanese pharmaceutical industries and contract laboratories made a database to evaluate drug effects on the QT interval in 2005. This QT PRODACT project was a prospective study of 12 QT-prolonging (positive) drugs and 10 non-prolonging (negative) drugs to evaluate the specificity and sensitivity of several in vivo and in vitro animal models: in vitro guinea pig papillary muscle action potential recordings and in vivo ECG recordings in unanesthetized or anesthetized beagle dogs, cynomolgus monkeys and miniature pigs. In guinea pig papillary muscle action potential recordings, positive drugs showed lengthening of the action potential duration (APD). By using a new measure to detect triangulation of the action potential configuration, an IKr blocking activity of drugs with Ca channel blocking action was detected. All in vivo studies showed a QT-prolonging effect of greater than 10% for the positive drugs. These in vivo models were useful to distinguish positive from negative drugs. The QT PRODACT project showed reliability and sensitivity of the experiments to detect positive drugs. The proarrhythmic effects of these positive drugs could not be detected even though, in some animal models (e.g., unanesthetized monkey), torsades de pointes (TdP)-type arrhythmias were shown by terfenadine. We compared in vivo arrhythmia models for proarrhythmia. The halothane-anesthetized open chest coronary occlusion-reperfusion canine model, the halothane-adrenaline arrhythmia model and the chronic AV block dog models seemed to be useful to detect the arrhythmogenic potential of QT-prolonging drugs.

Evaluation of the guinea pig monophasic action potential (MAP) assay in predicting drug-induced delay of ventricular repolarisation using 12 clinically documented drugs

INTRODUCTION

While the dog in vivo model is commonly employed in the later phase of discovery for assessing drug-induced QT prolongation, an early screening assay is valuable when selecting compounds for further development and when compound availability usually is low. One such screening assay is the anaesthetised guinea pig monophasic action potential (MAP) model. The aim of the present study was to evaluate the ability of this model to detect proarrhythmic properties by testing a set of reference compounds with known clinical profile. Moreover, these results were compared to data previously obtained using in vivo canine QT assays (QT PRODACT study).

METHODS

Anaesthetised and ventilated male guinea pigs were vagotomised and pretreated with propranolol. After thoracotomy, a pacing electrode was clipped to the left atrial appendage and a suction MAP electrode positioned on the left ventricular epicardium. The drug or corresponding vehicle was injected intravenously in cumulative doses and MAP duration at 90% repolarisation (MAPD90) was recorded during cardiac pacing.

RESULTS

The 8 drugs known to be proarrhythmic in the clinic all displayed dose-dependent prolongation of MAPD90, while the 4 drugs devoid of dysrhythmia in man had no effect. When comparing doses producing a 10% MAPD90 increase with doses reported to increase QTc by 10% in dogs a strong correlation was seen (R(2) 0.94 and 0.58 for anaesthetised and conscious dogs, respectively).

DISCUSSION

The guinea pig MAP assay identified all clinically positive drugs while negative drugs were without effect on ventricular repolarisation. Furthermore, a good concurrence is shown between the guinea pig and dog models in identifying compounds with proarrhythmic properties. Overall, the study reinforces the anaesthetised guinea pig MAP model as a reliable assay predicting QT liability of new chemical entities and as a highly sensitive early screening model for cardiovascular risk.

QT PRODACT: A Multi-site Study of In Vitro Action Potential Assays on 21 Compounds in Isolated Guinea-Pig Papillary Muscles

To construct a non-clinical database for drug-induced QT interval prolongation, the electrophysiological effects of 11 positive and 10 negative compounds on action potentials (AP) in guinea-pig papillary muscles were investigated in a multi-site study according to a standard protocol. Compounds with a selective inhibitory effect on the rapidly activated delayed rectifier potassium current (IKr) prolonged action potential duration at 90% repolarization (APD90) in a concentration-dependent manner, those showing Ca2+ current (ICa) inhibition shortened APD30, and those showing Na+ current (INa) inhibition decreased action potential amplitude (APA) and Vmax. Some of the mixed ion-channel blockers showed a bell-shaped concentration-response curve for APD90, probably due to their blockade of INa and/or ICa, sometimes leading to a false-negative result in the assay. In contrast, all positive compounds except for terfenadine and all negative compounds with IKr-blocking activity prolonged APD30-90 regardless of their INa- and/or ICa-blocking activities, suggesting that APD30-90 is a useful parameter for evaluating the IKr-blocking activity of test compounds. Furthermore, the assay is highly informative regarding the modulation of cardiac ion channels by test compounds. Therefore, when APD90 and APD30-90 are both measured, the action potential assay can be considered a useful method for assessing the risk of QT interval prolongation in humans in non-clinical safety pharmacology studies.

QT PRODACT: Comparison of Non-clinical Studies for Drug-Induced Delay in Ventricular Repolarization and Their Role in Safety Evaluation in Humans

Drug concentrations that would prolong repolarization parameters by 10%, including action potential duration (APD90, APD30-90), in in vitro assays using guinea-pig papillary muscle and QTc intervals in in vivo assays using conscious dogs, conscious monkeys, and anesthetized dogs were compared. Although, both the in vitro and in vivo assays showed concentration-dependent responses for compounds that have been classified as torsadogenic in humans, only a weak correlation in EC10 values was observed between the in vitro and in vivo assays. Among the in vivo QT assays, the EC10 values obtained from conscious dogs, conscious monkeys, and anesthetized dogs correlated well with each other, but the EC10 values in monkeys were somewhat lower in comparison to those in dogs. When in vivo QT assay EC10 values were compared to the respective human effective therapeutic plasma concentration (ETPC), the ratios of EC10 values to ETPCs were less than 20 for most torsadogenic compounds. In conclusion, the relationships between the extent of QTc interval prolongation and the concentration of drugs was highly consistent among the three in vivo models, suggesting that the ratios of EC10 values in in vivo QT assays are useful for estimating the safety margin of drugs that prolong the QTc interval.

QT PRODACT: Inter- and Intra-facility Variability of the Action Potential Assay Using Isolated Guinea-Pig Papillary Muscles

Sixteen pharmaceutical companies and 6 contract research organizations in QT PRODACT acquired data on the action potentials in isolated guinea-pig papillary muscles using a standard protocol established by the QT PRODACT. Inter- and intra-facility variability for each of the parameters in the pre-application values and Delta% change after vehicle (0.1% DMSO) or dl-sotalol (30 micromol/L) treatment were examined using a nested model. Inter-facility variability of each of the parameters in the pre-application values were Vmax>APDs=APD30-90>APA=RMP (descending order). The inter-facility variability of all of the parameters was almost the same or was less as compared with the intra-facility variability. Inter-facility variability for the Delta% change for each parameter after dl-sotalol treatment showed a tendency similar to the results for the pre-application values. Comparing the inter- and the intra-facility variability, the inter-facility variation did not exceed the intra-facility variation. All facilities found that dl-sotalol prolonged APD. Therefore, it is suggested that the test system using this standard protocol is useful as a non-clinical evaluation system for QT prolongation. Moreover, the results are considered to be directly comparable between multiple facilities.