Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm Modification

Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm Modification

PF‐05251749 is a dual inhibitor of casein kinase 1 δ/ε, key regulators of circadian rhythm. As a result of its mechanism of action, PF‐05251749 may also change the heart rate corrected QT (QTc) circadian rhythm, which may confound detection of drug‐induced QTc prolongation. In this analysis, a nonli...

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Main Authors: Yeamin Huh, Danny Chen, Steve Riley, Cheng Chang, Timothy Nicholas
Format: Article
Language:English
Published: Wiley 2020-01-01
Series:CPT: Pharmacometrics & Systems Pharmacology
Online Access:https://doi.org/10.1002/psp4.12483
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spelling doaj-cd7b2b302016406eb7aaa99959a23eec2020-11-25T02:58:34ZengWileyCPT: Pharmacometrics & Systems Pharmacology2163-83062020-01-0191606910.1002/psp4.12483Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm ModificationYeamin Huh0Danny Chen1Steve Riley2Cheng Chang3Timothy Nicholas4Global Product Development Pfizer Inc Groton Connecticut USAEarly Clinical Development Pfizer Inc Cambridge Massachusetts USAGlobal Product Development Pfizer Inc Groton Connecticut USAGlobal Product Development Pfizer Inc Groton Connecticut USAGlobal Product Development Pfizer Inc Groton Connecticut USAPF‐05251749 is a dual inhibitor of casein kinase 1 δ/ε, key regulators of circadian rhythm. As a result of its mechanism of action, PF‐05251749 may also change the heart rate corrected QT (QTc) circadian rhythm, which may confound detection of drug‐induced QTc prolongation. In this analysis, a nonlinear mixed effect model including a multioscillator function was developed in addition to fitting the prespecified linear mixed effect concentration‐QTc model, to identify QTc liability of PF‐05251749 in the presence of potential circadian rhythm change. The modeling results suggested lack of clinically meaningful QTc prolongation (upper bound of 90% confidence interval for ∆∆QTc < 10 milliseconds) and that the drug‐induced QTc circadian rhythm change was not present. However, simulation results indicated that inference of drug‐induced QTc prolongation could be misleading if the drug effect on QTc circadian rhythm is not properly addressed. The modeling and simulation results suggest that prespecification of the concentration‐QTc model should be reconsidered for drugs with circadian rhythm modulation potential.https://doi.org/10.1002/psp4.12483
collection DOAJ
language English
format Article
sources DOAJ
author Yeamin Huh
Danny Chen
Steve Riley
Cheng Chang
Timothy Nicholas
spellingShingle Yeamin Huh
Danny Chen
Steve Riley
Cheng Chang
Timothy Nicholas
Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm Modification
CPT: Pharmacometrics & Systems Pharmacology
author_facet Yeamin Huh
Danny Chen
Steve Riley
Cheng Chang
Timothy Nicholas
author_sort Yeamin Huh
title Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm Modification
title_short Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm Modification
title_full Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm Modification
title_fullStr Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm Modification
title_full_unstemmed Evaluation of QT Liability for PF‐05251749 in the Presence of Potential Circadian Rhythm Modification
title_sort evaluation of qt liability for pf‐05251749 in the presence of potential circadian rhythm modification
publisher Wiley
series CPT: Pharmacometrics & Systems Pharmacology
issn 2163-8306
publishDate 2020-01-01
description PF‐05251749 is a dual inhibitor of casein kinase 1 δ/ε, key regulators of circadian rhythm. As a result of its mechanism of action, PF‐05251749 may also change the heart rate corrected QT (QTc) circadian rhythm, which may confound detection of drug‐induced QTc prolongation. In this analysis, a nonlinear mixed effect model including a multioscillator function was developed in addition to fitting the prespecified linear mixed effect concentration‐QTc model, to identify QTc liability of PF‐05251749 in the presence of potential circadian rhythm change. The modeling results suggested lack of clinically meaningful QTc prolongation (upper bound of 90% confidence interval for ∆∆QTc < 10 milliseconds) and that the drug‐induced QTc circadian rhythm change was not present. However, simulation results indicated that inference of drug‐induced QTc prolongation could be misleading if the drug effect on QTc circadian rhythm is not properly addressed. The modeling and simulation results suggest that prespecification of the concentration‐QTc model should be reconsidered for drugs with circadian rhythm modulation potential.
url https://doi.org/10.1002/psp4.12483
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