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Prediction of human drug clearance and anticipation of clinical drug-drug interaction potential from in vitro drug transport studies

Kunze, Annett. Prediction of human drug clearance and anticipation of clinical drug-drug interaction potential from in vitro drug transport studies. 2014, Doctoral Thesis, University of Basel, Faculty of Science.

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Official URL: http://edoc.unibas.ch/diss/DissB_11053

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Abstract

A major concern in drug development is the characterization of new molecular entities (NMEs) with respect to their safety and efficacy. Both factors are determined by the drug’s exposure within the body which itself is affected by drug clearance processes. The major clearance organs are the liver and the kidney, where an interplay of metabolic enzymes and drug transporters mediates the elimination of drugs by metabolism and/or secretion. By that, inhibition of active clearance pathways, as observed from drug-drug interactions (DDIs), can result in alterations in a drug’s exposure. Therefore, the early characterization of the pharmacokinetic profile (PK) of NMEs is a major goal in preclinical drug development. However, due to lacking human in vivo PK data in this early phase of drug development, in vitro-based methods are commonly used to make a first assessment of the PK profile of NMEs. Consequently, the development, validation, and characterization of these methods is of major importance. Therefore, it was the aim of this work to investigate the prediction of human renal and hepatic drug clearances by in vitro-in vivo extrapolation (IVIVE) models and assess their feasibility to predict the DDI potential of drugs in human.
To date, only few IVIVE approaches have been described to predict the human renal organ clearance based on filtration, secretion, and reabsorption. In a first study, we measured in LLC-PK1 cells the transport of 20 compounds with various physiochemical and PK properties. These data were incorporated into a novel kidney model to predict all renal clearance processes in human. Compared to reported renal clearances from clinical studies, the prediction accuracy in terms of percentage within three-fold error was 95%. Moreover, our model allowed the assessment of the contribution of filtration, secretion, and reabsorption to the net renal organ clearance in human.
In a second study, we investigated the contribution of the organic anion transporting polypeptides (OATP) 1 and OATP1B3 to the net hepatic uptake clearance of statins. For this purpose, the absolute transporter protein abundances were determined by liquid chromatography-tandem mass spectrometry in cryopreserved human hepatocytes and single-transporter expressing HEK293 cells. Subsequently, uptake kinetics of eight statins and OATP1B1 and OATP1B3-specific reference substrates were determined in all expression systems. Transporter activity data generated in recombinant cell lines were extrapolated to hepatocyte values using relative transporter expression factors (REF) or relative activity factors (RAF). We showed that REF and RAF-based predictions were highly similar indicating a direct transporter expression-activity relationship. Moreover, we demonstrated that the REF-scaling method provided a powerful tool to quantitatively assess the transporter-specific contributions to the net uptake clearance of statins in hepatocytes.
In a third study, we applied a recently developed IVIVE method to predict the human hepatic clearance and the DDI potential of eight statins. Application of the recently established Extended Clearance Concept Classification System (ECCCS), demonstrated a good predictability of the human hepatic clearance with six out of eight statins projected within a two-fold deviation to reported values. Furthermore, the DDI potential of the statins was assessed with respect to the impact of possible perpetrator drugs on hepatic uptake, metabolism, and biliary secretion and subsequently compared with reported clinical DDI effects. The predicted DDIs for statins showed excellent quantitative correlations with clinical observations. The ECCCS thus represents a powerful tool to anticipate the DDI potential of victim drugs based on in vitro drug metabolism and transport data.
In a last study, we assessed the inhibitory potential of telaprevir, a new, direct-acting antiviral drug, on major human renal and hepatic drug transporters. By that, co-incubations of drug-transporter reference substrates and telaprevir in stable, single-transporter transfected HEK293 cells was investigated. Our data showed that telaprevir exhibited significant potential to inhibit major renal and hepatic drug transporters in human. Therefore, clinical co-administration of telaprevir together with drugs that are substrates of renal and hepatic transporters should be carefully monitored.
Taken together, with the help of this work the safety profiles of NMEs can now be assessed in preclinical drug development based on in vitro methods. It is therefore expected, that the establishment, validation, and application of novel in vitro based methods, described in this work, will add significant value in the early assessment of the PK profile of NMEs.
Advisors:Huwyler, Jörg
Committee Members:Camenisch, Gian and Meyer zu Schwabedissen, Henriette E.
Faculties and Departments:05 Faculty of Science > Departement Pharmazeutische Wissenschaften > Pharmazie > Pharmaceutical Technology (Huwyler)
UniBasel Contributors:Huwyler, Jörg
Item Type:Thesis
Thesis Subtype:Doctoral Thesis
Thesis no:11053
Thesis status:Complete
Number of Pages:114 S.
Language:English
Identification Number:
edoc DOI:
Last Modified:22 Apr 2018 04:31
Deposited On:23 Dec 2014 13:17

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