Induced pluripotent stem cell-derived cardiomyocytes (iPSC-CM) hold promise for assessment of drug-induced arrhythmias and are being considered for use under the comprehensive in vitro proarrhythmia assay (CiPA). We studied the effects of 26 drugs and 3 drug combinations on 2 commercially available iPSC-CM types using high-throughput voltage-sensitive dye and microelectrode-array assays being studied for the CiPA initiative and compared the results with clinical QT prolongation and torsade de pointes (TdP) risk. Concentration-dependent analysis comparing iPSC-CMs to clinical trial results demonstrated good correlation between drug-induced rate-corrected action potential duration and field potential duration (APDc and FPDc) prolongation and clinical trial QTc prolongation. Of 20 drugs studied that exhibit clinical QTc prolongation, 17 caused APDc prolongation (16 in Cor.4U and 13 in iCell cardiomyocytes) and 16 caused FPDc prolongation (16 in Cor.4U and 10 in iCell cardiomyocytes). Of 14 drugs that cause TdP, arrhythmias occurred with 10 drugs. Lack of arrhythmic beating in iPSC-CMs for the four remaining drugs could be due to differences in relative levels of expression of individual ion channels. iPSC-CMs responded consistently to human ether-a-go-go potassium channel blocking drugs (APD prolongation and arrhythmias) and calcium channel blocking drugs (APD shortening and prevention of arrhythmias), with a more variable response to late sodium current blocking drugs. Current results confirm the potential of iPSC-CMs for proarrhythmia prediction under CiPA, where iPSC-CM results would serve as a check to ion channel and in silico modeling prediction of proarrhythmic risk. A multi-site validation study is warranted.
Drug-induced long QT syndrome has resulted in many drugs being withdrawn from the market. At the same time, the current regulatory paradigm for screening new drugs causing long QT syndrome is preventing drugs from reaching the market, sometimes inappropriately. In this study, we report the results of a first-of-a-kind clinical trial studying late sodium (mexiletine and lidocaine) and calcium (diltiazem) current blocking drugs to counteract the effects of hERG potassium channel blocking drugs (dofetilide and moxifloxacin). We demonstrate that both mexiletine and lidocaine substantially reduce heart-rate corrected QT (QTc) prolongation from dofetilide by 20 ms. Furthermore, all QTc shortening occurs in the heart-rate corrected J-T peak (J-T peak c) interval, the biomarker we identified as a sign of late sodium current block. This clinical trial demonstrates that late sodium blocking drugs can substantially reduce QTc prolongation from Correspondence: DG Strauss David.Strauss@fda.hhs.gov. Additional Supporting Information may be found in the online version of this article.Author Contributions: All authors have contributed as follows: protocol development (L.J., J.V., J.W.M., C.S., K.W.L., J.F., N.S., D.G.S.), data collection (C.E., C.S., K.W.L., M.H., J.L., P.G., A.M., J.W., W.J.C.), data analysis (L.J., J.V., J.F., D.G.S.), and preparing the manuscript (L.J., D.G.S.). All authors discussed the results and implications and commented on the manuscript. Conflict of HHS Public Access Author Manuscript Author ManuscriptAuthor ManuscriptAuthor Manuscript hERG potassium channel block and assessment of J-T peak c may add value beyond only assessing QTc.Drug-induced QT prolongation increases the risk for torsade de pointes, a potentially fatal ventricular arrhythmia. 1 QT prolongation and increased risk for torsade de pointes have resulted in 14 drugs being removed from the market worldwide. 2 Furthermore, many drugs remain on the market with a known torsade de pointes risk, including numerous antibiotics, antimalarial, antiviral, psychiatric, oncology, and cardiac drugs. 3 At the same time, the current regulatory paradigm for assessing drug effects on cardiac repolarization is preventing potentially effective medicines from reaching the market, sometimes inappropriately. 2 To address this, the US Food and Drug Administration (FDA) and multiple public-private partnerships are studying novel approaches to assess the cardiac safety of new drugs with a Comprehensive in vitro Proarrhythmia Assay and in Phase 1 clinical trials. 4,5 Essential to the novel approaches is a focus on understanding mechanisms by studying the effects of drugs on multiple cardiac ion channels, which can be either proarrhythmic or antiarrhythmic depending on the combination. 6Almost all drugs on the market that can cause torsade de pointes block the hERG potassium channel 7 and prolong the QT interval of the electrocardiogram (ECG). 8 However, some drugs block the hERG potassium channel and prolong QT with a minimal torsade de pointes risk (e....
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