Real Patient and its Virtual Twin: Application of Quantitative Systems Toxicology Modelling in the Cardiac Safety Assessment of Citalopram

A quantitative systems toxicology (QST) model for citalopram was established to simulate, in silico, a ‘virtual twin’ of a real patient to predict the occurrence of cardiotoxic events previously reported in patients under various clinical conditions. The QST model considers the effects of citalopram and its most notable electrophysiologically active primary (desmethylcitalopram) and secondary (didesmethylcitalopram) metabolites, on cardiac electrophysiology. The in vitro cardiac ion channel current inhibition data was coupled with the biophysically detailed model of human cardiac electrophysiology to investigate the impact of (i) the inhibition of multiple ion currents (IKr, IKs, ICaL); (ii) the inclusion of metabolites in the QST model; and (iii) unbound or total plasma as the operating drug concentration, in predicting clinically observed QT prolongation. The inclusion of multiple ion channel current inhibition and metabolites in the simulation with unbound plasma citalopram concentration provided the lowest prediction error. The predictive performance of the model was verified with three additional therapeutic and supra-therapeutic drug exposure clinical cases. The results indicate that considering only the hERG ion channel inhibition of only the parent drug is potentially misleading, and the inclusion of active metabolite data and the influence of other ion channel currents should be considered to improve the prediction of potential cardiac toxicity. Mechanistic modelling can help bridge the gaps existing in the quantitative translation from preclinical cardiac safety assessment to clinical toxicology. Moreover, this study shows that the QST models, in combination with appropriate drug and systems parameters, can pave the way towards personalised safety assessment.

[1]  A. Cave,et al.  Should We be Worried About QTc Prolongation Using Citalopram? A Review , 2017, Journal of pharmacy practice.

[2]  Mitra Abbasi,et al.  Early assessment of proarrhythmic risk of drugs using the in vitro data and single-cell-based in silico models: proof of concept , 2017, Toxicology mechanisms and methods.

[3]  Sebastian Polak,et al.  A four-compartment PBPK heart model accounting for cardiac metabolism - model development and application , 2017, Scientific reports.

[4]  S. Polak,et al.  Am I or am I not proarrhythmic? Comparison of various classifications of drug TdP propensity. , 2017, Drug discovery today.

[5]  G. Tucker Personalized Drug Dosage – Closing the Loop , 2016, Pharmaceutical Research.

[6]  S. Polak,et al.  Virtual Clinical Trial Toward Polytherapy Safety Assessment: Combination of Physiologically Based Pharmacokinetic/Pharmacodynamic-Based Modeling and Simulation Approach With Drug-Drug Interactions Involving Terfenadine as an Example. , 2016, Journal of pharmaceutical sciences.

[7]  Sebastian Polak,et al.  The Role of Interaction Model in Simulation of Drug Interactions and QT Prolongation , 2016, Current Pharmacology Reports.

[8]  Ioannis P. Androulakis,et al.  Physiologically-based pharmacokinetic models: approaches for enabling personalized medicine , 2016, Journal of Pharmacokinetics and Pharmacodynamics.

[9]  T. Colatsky,et al.  The Comprehensive in Vitro Proarrhythmia Assay (CiPA) initiative - Update on progress. , 2016, Journal of pharmacological and toxicological methods.

[10]  Jean-Frédéric Gerbeau,et al.  Comprehensive in vitro Proarrhythmia Assay (CiPA): Pending issues for successful validation and implementation. , 2016, Journal of pharmacological and toxicological methods.

[11]  D. Strauss,et al.  An evaluation of 30 clinical drugs against the comprehensive in vitro proarrhythmia assay (CiPA) proposed ion channel panel. , 2016, Journal of pharmacological and toxicological methods.

[12]  Masoud Jamei,et al.  Recent Advances in Development and Application of Physiologically-Based Pharmacokinetic (PBPK) Models: a Transition from Academic Curiosity to Regulatory Acceptance , 2016, Current Pharmacology Reports.

[13]  S. Polak,et al.  Drug-drug interactions and QT prolongation as a commonly assessed cardiac effect - comprehensive overview of clinical trials , 2016, BMC Pharmacology and Toxicology.

[14]  Sebastian Polak,et al.  Plasma vs heart tissue concentration in humans - literature data analysis of drugs distribution. , 2015, Biopharmaceutics & drug disposition.

[15]  S. Bugden,et al.  The effectiveness and limitations of regulatory warnings for the safe prescribing of citalopram , 2015, Drug, healthcare and patient safety.

[16]  D. Schaid,et al.  Citalopram and escitalopram plasma drug and metabolite concentrations: genome-wide associations. , 2014, British Journal of Clinical Pharmacology.

[17]  S. Polak,et al.  In vitro-in vivo extrapolation of drug-induced proarrhythmia predictions at the population level. , 2014, Drug discovery today.

[18]  R. Temple,et al.  Cardiac safety concerns remain for citalopram at dosages above 40 mg/day. , 2014, The American journal of psychiatry.

[19]  Kamil Fijorek,et al.  Circadian Models of Serum Potassium, Sodium, and Calcium Concentrations in Healthy Individuals and Their Application to Cardiac Electrophysiology Simulations at Individual Level , 2013, Comput. Math. Methods Medicine.

[20]  Kairui Feng,et al.  The Simcyp Population Based Simulator: Architecture, Implementation, and Quality Assurance , 2013, In Silico Pharmacology.

[21]  K. Zivin,et al.  Evaluation of the FDA warning against prescribing citalopram at doses exceeding 40 mg. , 2013, The American journal of psychiatry.

[22]  N. Patel,et al.  Age and gender dependent heart rate circadian model development and performance verification on the proarrhythmic drug case study , 2013, Theoretical Biology and Medical Modelling.

[23]  J. Rohrbacher,et al.  Citalopram metabolites inhibit IKs and IKr differentially: Is this a possible explanation for the sudden deaths in dogs? , 2012 .

[24]  N. Segal,et al.  What Virtual Twins Reveal About General Intelligence and Other Behaviors. , 2012, Personality and individual differences.

[25]  Sebastian Polak,et al.  Inter-individual Variability in the Pre-clinical Drug Cardiotoxic Safety Assessment—Analysis of the Age–Cardiomyocytes Electric Capacitance Dependence , 2012, Journal of Cardiovascular Translational Research.

[26]  S. Polak,et al.  Virtual population generator for human cardiomyocytes parameters: in silico drug cardiotoxicity assessment , 2012, Toxicology mechanisms and methods.

[27]  J. Deckert,et al.  Correlation of QTc Interval Prolongation and Serum Level of Citalopram after Intoxication – A Case Report , 2011, Pharmacopsychiatry.

[28]  F. Coudoré,et al.  Drug monitoring of a case of citalopram overdosage , 2011, Drug and chemical toxicology.

[29]  Kairui Feng,et al.  The Simcyp® Population-based ADME Simulator , 2009 .

[30]  R. Hoffman,et al.  Citalopram overdose: Late presentation of torsades de pointes (TdP) with cardiac arrest , 2008, Journal of medical toxicology : official journal of the American College of Medical Toxicology.

[31]  Kairui Feng,et al.  The Simcyp population-based ADME simulator. , 2009, Expert opinion on drug metabolism & toxicology.

[32]  K. T. ten Tusscher,et al.  Alternans and spiral breakup in a human ventricular tissue model. , 2006, American journal of physiology. Heart and circulatory physiology.

[33]  Lena E Friberg,et al.  Pharmacokinetic-pharmacodynamic modelling of QT interval prolongation following citalopram overdoses. , 2006, British journal of clinical pharmacology.

[34]  Y. Sawada,et al.  Quantitative Relationship Between Myocardial Concentration of Tacrolimus and QT Prolongation in Guinea Pigs: Pharmacokinetic/Pharmacodynamic Model Incorporating a Site of Adverse Effect , 2001, Journal of Pharmacokinetics and Pharmacodynamics.

[35]  Peter L. Bonate,et al.  Clinical Trial Simulation in Drug Development , 2000, Pharmaceutical Research.

[36]  Mario Lobell,et al.  In silico prediction of aqueous solubility, human plasma protein binding and volume of distribution of compounds from calculated pKa and AlogP98 values , 2004, Molecular Diversity.

[37]  Jules C Hancox,et al.  Inhibitory actions of the selective serotonin re‐uptake inhibitor citalopram on HERG and ventricular L‐type calcium currents , 2002, FEBS letters.

[38]  J. Slavicek,et al.  Citalopram inhibits L-type calcium channel current in rat cardiomyocytes in culture. , 2002, Physiological research.

[39]  Z. Ungvari,et al.  Speculations on difference between tricyclic and selective serotonin reuptake inhibitor antidepressants on their cardiac effects. Is there any? , 1999, Current medicinal chemistry.

[40]  H. Bazett,et al.  AN ANALYSIS OF THE TIME‐RELATIONS OF ELECTROCARDIOGRAMS. , 1997 .