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dc.contributor.authorBoulay, Emmanuel
dc.contributor.authorTroncy, Éric
dc.contributor.authorJacquemet, Vincent
dc.contributor.authorHuang, Hai
dc.contributor.authorPugsley, Michael
dc.contributor.authorDowney, Anne-Marie
dc.contributor.authorVenegas Baca, Rafael
dc.contributor.authorAuthier, Simon
dc.date.accessioned2024-08-26T14:46:06Z
dc.date.availableNO_RESTRICTIONfr
dc.date.available2024-08-26T14:46:06Z
dc.date.issued2024-03-13
dc.identifier.urihttp://hdl.handle.net/1866/33748
dc.publisherSAGEfr
dc.subjectIn silicofr
dc.subjectO’Hara Rudy modelfr
dc.subjectAction potential durationfr
dc.subjectTorsade de pointesfr
dc.subjecthERGfr
dc.subjectCiPAfr
dc.titleIn silico human cardiomyocyte action potential modeling : exploring ion channel input combinationsfr
dc.typeArticlefr
dc.contributor.affiliationUniversité de Montréal. Faculté de médecine. Département de pharmacologie et physiologiefr
dc.identifier.doi10.1177/10915818241237988
dcterms.abstractIn silico modeling offers an opportunity to supplement and accelerate cardiac safety testing. With in silico modeling, computational simulation methods are used to predict electrophysiological interactions and pharmacological effects of novel drugs on critical physiological processes. The O’Hara-Rudy’s model was developed to predict the response to different ion channel inhibition levels on cardiac action potential duration (APD) which is known to directly correlate with the QT interval. APD data at 30% 60% and 90% inhibition were derived from the model to delineate possible ventricular arrhythmia scenarios and the marginal contribution of each ion channel to the model. Action potential values were calculated for epicardial, myocardial, and endocardial cells, with action potential curve modeling. This study assessed cardiac ion channel inhibition data combinations to consider when undertaking in silico modeling of proarrhythmic effects as stipulated in the Comprehensive in Vitro Proarrhythmia Assay (CiPA). As expected, our data highlight the importance of the delayed rectifier potassium channel (IKr) as the most impactful channel for APD prolongation. The impact of the transient outward potassium channel (Ito) inhibition on APD was minimal while the inward rectifier (IK1) and slow component of the delayed rectifier potassium channel (IKs) also had limited APD effects. In contrast, the contribution of fast sodium channel (INa) and/or L-type calcium channel (ICa) inhibition resulted in substantial APD alterations supporting the pharmacological relevance of in silico modeling using input from a limited number of cardiac ion channels including IKr, INa, and ICa, at least at an early stage of drug development.fr
dcterms.isPartOfurn:ISSN:1091-5818fr
dcterms.isPartOfurn:ISSN:1092-874Xfr
dcterms.languageengfr
UdeM.ReferenceFournieParDeposantDOI: 10.1177/10915818241237988fr
UdeM.VersionRioxxVersion acceptée / Accepted Manuscriptfr
oaire.citationTitleInternational journal of toxicologyfr
oaire.citationVolume43fr
oaire.citationIssue4fr
oaire.citationStartPage357fr
oaire.citationEndPage367fr


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