Physiologically Based Pharmacokinetic Modeling to Predict Drug-Drug Interactions Involving Inhibitory Metabolite: A Case Study of Amiodarone

Chen, Yuan; Mao, Jialin; Hop, Cornelis E. C. A.

doi:10.1124/dmd.114.059311

Cited by 47 publications

(38 citation statements)

References 34 publications

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“…Not surprisingly, since kinetic inhibition parameters can often differ considerably depending on the literature source, there are some significant differences in the K i , K I , and k inact values the authors used to generate their predictions compared with those reported here. However, it is of particular interest that, considering only AMIO and MDEA inhibition parameters, the model of Chen et al, (2015) appears to substantially underpredict the wellknown warfarin-AMIO DDI. This discrepancy is in line with our contention that the minor AMIO metabolite, DDEA, is the primary culprit in AMIO DDIs involving CYP2C9.…”

Section: Discussionmentioning

confidence: 99%

P450-Based Drug-Drug Interactions of Amiodarone and its Metabolites: Diversity of Inhibitory Mechanisms

McDonald

Rettie

2015

Drug Metab Dispos

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In this study, IC 50 shift and time-dependent inhibition (TDI) experiments were carried out to measure the ability of amiodarone (AMIO), and its circulating human metabolites, to reversibly and irreversibly inhibit CYP1A2, CYP2C9, CYP2D6, and CYP3A4 activities in human liver microsomes. The [I] u /K i,u values were calculated and used to predict in vivo AMIO drug-drug interactions (DDIs) for pharmaceuticals metabolized by these four enzymes. Based on these values, the minor metabolite N,N-didesethylamiodarone (DDEA) is predicted to be the major cause of DDIs with xenobiotics primarily metabolized by CYP1A2, CYP2C9, or CYP3A4, while AMIO and its N-monodesethylamiodarone (MDEA) derivative are the most likely cause of interactions involving inhibition of CYP2D6 metabolism. AMIO drug interactions predicted from the reversible inhibition of the four P450 activities were found to be in good agreement with the magnitude of reported clinical DDIs with lidocaine, warfarin, metoprolol, and simvastatin. The TDI experiments showed DDEA to be a potent inactivator of CYP1A2 (K I = 0.46 mM, k inact = 0.030 minute 21 ), while MDEA was a moderate inactivator of both CYP2D6 (K I = 2.7 mM, k inact = 0.018 minute 21) and CYP3A4 (K I = 2.6 mM, k inact = 0.016 minute 21). For DDEA and MDEA, mechanism-based inactivation appears to occur through formation of a metabolic intermediate complex.Additional metabolic studies strongly suggest that CYP3A4 is the primary microsomal enzyme involved in the metabolism of AMIO to both MDEA and DDEA. In summary, these studies demonstrate both the diversity of inhibitory mechanisms with AMIO and the need to consider metabolites as the culprit in inhibitory P450-based DDIs.

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Section: Discussionmentioning

confidence: 99%

P450-Based Drug-Drug Interactions of Amiodarone and its Metabolites: Diversity of Inhibitory Mechanisms

McDonald

Rettie

2015

Drug Metab Dispos

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“…For example, more complex absorption models such as advanced dissolution, absorption, and metabolism (ADAM) models (Jamei et al, 2009b) and advanced compartmental absorption and transit (ACAT) models (Agoram et al, 2001) have been developed that enable the use of PBPK modeling for the simulation of food effects (Shono et al, 2009;Turner et al, 2012;Heimbach et al, 2013;Xia et al, 2013b;Patel et al, 2014;Zhang et al, 2014), the impact of drug properties on absorption kinetics (Kambayashi et al, 2013;Parrott et al, 2014), and intestinal interactions (Fenneteau et al, 2010). The development of sophisticated models that allow for the simulation of multiple inhibitors or inducers, relevant metabolites, and multiple mechanisms of interaction have permitted the prediction of complex DDIs involving enzymes, transporters, and multiple interaction mechanisms Reki c et al, 2011;Varma et al, 2012Varma et al, , 2013Dhuria et al, 2013;Gertz et al, 2013Gertz et al, , 2014Guo et al, 2013;Kudo et al, 2013;Siccardi et al, 2013;Wang et al, 2013a;Sager et al, 2014;Chen et al, 2015;Shi et al, 2015). Furthermore, the mechanistic understanding of ADME changes that occur in different age groups or disease states has improved, and consequently PBPK modeling has been used to simulate drug disposition in special populations including hepatic (Johnson et al, 2014) and renal impairment populations (Li et al, 2012;Zhao et al, 2012a;Lu et al, 2014;Sayama et al, 2014), children (Leong et al, 2012), and pregnant women (Andrew et al, 2008;Gaohua et al, 2012;…”

Section: Introductionmentioning

confidence: 99%

Physiologically Based Pharmacokinetic (PBPK) Modeling and Simulation Approaches: A Systematic Review of Published Models, Applications, and Model Verification

et al. 2015

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Modeling and simulation of drug disposition has emerged as an important tool in drug development, clinical study design and regulatory review, and the number of physiologically based pharmacokinetic (PBPK) modeling related publications and regulatory submissions have risen dramatically in recent years. However, the extent of use of PBPK modeling by researchers, and the public availability of models has not been systematically evaluated. This review evaluates PBPK-related publications to 1) identify the common applications of PBPK modeling; 2) determine ways in which models are developed; 3) establish how model quality is assessed; and 4) provide a list of publically available PBPK models for sensitive P450 and transporter substrates as well as selective inhibitors and inducers. PubMed searches were conducted using the terms "PBPK" and "physiologically based pharmacokinetic model" to collect published models. Only papers on PBPK modeling of pharmaceutical agents in humans published in English between 2008 and May 2015 were reviewed. A total of 366 PBPK-related articles met the search criteria, with the number of articles published per year rising steadily. Published models were most commonly used for drug-drug interaction predictions (28%), followed by interindividual variability and general clinical pharmacokinetic predictions (23%), formulation or absorption modeling (12%), and predicting age-related changes in pharmacokinetics and disposition (10%). In total, 106 models of sensitive substrates, inhibitors, and inducers were identified. An in-depth analysis of the model development and verification revealed a lack of consistency in model development and quality assessment practices, demonstrating a need for development of best-practice guidelines.

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“…The pony PBPK model [58] consisted of limited number of tissue compartments, including blood, liver, kidney, fat, rapidly perfused tissues, and slowly perfused tissues. Although the human PBPK model [59] included more tissues, it may not provide insight into the kinetic behaviors of AMD in tissues since the predicted concentration-time profiles in most tissues cannot be evaluated due to the lack of observed data. Apparently, gaining insight into the kinetic behaviors of a drug in more organs is highly desirable, particularly in therapeutic target organs and those to which the compound may be potentially harmful.…”

Section: Discussionmentioning

confidence: 98%

“…One model [58] described the disposition of AMD and DEA in ponies and another one [59] was developed in humans. The pony PBPK model [58] consisted of limited number of tissue compartments, including blood, liver, kidney, fat, rapidly perfused tissues, and slowly perfused tissues.…”

Section: Discussionmentioning

confidence: 99%

A Physiologically Based Pharmacokinetic Model of Amiodarone and its Metabolite Desethylamiodarone in Rats: Pooled Analysis of Published Data

Cai

Chen

et al. 2015

Eur J Drug Metab Pharmacokinet

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Physiologically Based Pharmacokinetic Modeling to Predict Drug-Drug Interactions Involving Inhibitory Metabolite: A Case Study of Amiodarone

Cited by 47 publications

References 34 publications

P450-Based Drug-Drug Interactions of Amiodarone and its Metabolites: Diversity of Inhibitory Mechanisms

P450-Based Drug-Drug Interactions of Amiodarone and its Metabolites: Diversity of Inhibitory Mechanisms

Physiologically Based Pharmacokinetic (PBPK) Modeling and Simulation Approaches: A Systematic Review of Published Models, Applications, and Model Verification

A Physiologically Based Pharmacokinetic Model of Amiodarone and its Metabolite Desethylamiodarone in Rats: Pooled Analysis of Published Data

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