Development and validation of a physiology-based model for the prediction of pharmacokinetics/toxicokinetics in rabbits

Mavroudis, Panteleimon D.; Hermes, Helen E.; Teutonico, Donato; Preuß, Thomas G.; Schneckener, Sebastian

doi:10.1371/journal.pone.0194294

Cited by 20 publications

(25 citation statements)

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“…This implies in particular the application of best practice standards for model development and model qualification which are largely supported by full documentation and accessibility of the free and open PBPK software PK-Sim from the OSP software suite (OSP: open system pharmacology, https://www.open-systems-pharmacology.org ). In that sense, the previously published rabbit PBPK model (Mavroudis et al 2018 ) can be seen as a blueprint of our concept since it fulfils all requirements in terms of accessibility, reproducibility and qualification. Of note, the workflow applied is independent of the specific PBTK software used, but represents rather a generic concept of broad applicability for the identification of key model parameters, which can then be used to efficiently build PBTK models for novel species.…”

Section: Introductionmentioning

confidence: 97%

“…In contrast, the term “PBTK model” describes the full PBTK model including administration of a substance. Available and validated mammalian species models include human (Kuepfer et al 2016 ; Willmann et al 2003a ), monkey (Willmann et al 2007 ), minipig, dog (Willmann et al 2010 ), mouse (Schenk et al 2017 ; Thiel et al 2015 ), rat (Willmann et al 2003b ), and a recently developed rabbit model (Mavroudis et al 2018 ). For a broader applicability of PBTK models, it would clearly be desirable to have models for more species, e.g.…”

Section: Introductionmentioning

confidence: 99%

“…adopting the values from other mammalian species or calculating the value by means of extrapolation to limit the overall effort necessary. This approach was successfully taken for the parameterisation of the rabbit model (Mavroudis et al 2018 ).…”

Section: Introductionmentioning

confidence: 99%

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A workflow to build PBTK models for novel species

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Physiology-based pharmacokinetic and toxicokinetic (PBPK/TK) models allow us to simulate the concentration of xenobiotica in the plasma and different tissues of an organism. PBPK/TK models are therefore routinely used in many fields of life sciences to simulate the physiological concentration of exogenous compounds in plasma and tissues. The application of PBTK models in ecotoxicology, however, is currently hampered by the limited availability of models for focal species. Here, we present a best practice workflow that describes how to build PBTK models for novel species. To this end, we extrapolated eight previously established rabbit models for several drugs to six additional mammalian species (human, beagle, rat, monkey, mouse, and minipig). We used established PBTK models for these species to account for the species-specific physiology. The parameter sensitivity in the resulting 56 PBTK models was systematically assessed to rank the relevance of the parameters on overall model performance. Interestingly, more than 80% of the 609 considered model parameters showed a negligible sensitivity throughout all models. Only approximately 5% of all parameters had a high sensitivity in at least one of the PBTK models. This approach allowed us to rank the relevance of the various parameters on overall model performance. We used this information to formulate a best practice guideline for the efficient development of PBTK models for novel animal species. We believe that the workflow proposed in this study will significantly support the development of PBTK models for new animal species in the future.

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Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

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A workflow to build PBTK models for novel species

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“…Currently, mPBPK models can be developed through typical software platforms such as WinNonlin (Certara, Princeton, NJ, USA), NONMEM (ICON plc, Gaithersburg, MD, USA), ADAPT (BMSR Biomedical Simulations Resource, University of Southern California, Los Angeles, CA, USA), MATLAB (MathWorks, Natick, MA, USA), and many others as there is no specific computational tool needed for mPBPK modeling and simulation except for numerical integration. However, the critical steps of model development, verification, and validation such as sensitivity analysis (SA) of PK parameters are not part of the software design, and most of the time are cumbersome to perform . In this tutorial, we describe a new MATLAB‐based tool for the modeling and simulation of mPBPK models (ATLAS mPBPK).…”

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confidence: 99%

“…However, the critical steps of model development, verification, and validation such as sensitivity analysis (SA) of PK parameters are not part of the software design, and most of the time are cumbersome to perform. [13][14][15][16] In this tutorial, we describe a new MATLAB-based tool for the modeling and simulation of mPBPK models (ATLAS mPBPK). This software offers a number of different predefined mPBPK models based on which the user can perform the following: (i) simulations, (ii) parameter optimization, and (iii) SA.…”

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confidence: 99%

ATLAS mPBPK: A MATLAB‐Based Tool for Modeling and Simulation of Minimal Physiologically‐Based Pharmacokinetic Models

Mavroudis

Ayyar

Jusko

2019

CPT Pharmacom & Syst Pharma

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Minimal physiologically‐based pharmacokinetic ( mPBPK ) models are frequently used to model plasma pharmacokinetic (PK) data and utilize and yield physiologically relevant parameters. Compared with classical compartment and whole‐body physiologically‐based pharmacokinetic modeling approaches, mPBPK models maintain a structure of intermediate physiological complexity that can be adequately informed by plasma PK data. In this tutorial, we present a MATLAB ‐based tool for the modeling and simulation of mPBPK models ( ATLAS mPBPK ) of small and large molecules. This tool enables the users to perform the following: (i) PK data visualization, (ii) simulation, (iii) parameter optimization, and (iv) local sensitivity analysis of mPBPK models in a simple and efficient manner. In addition to the theoretical background and implementation of the different tool functionalities, this tutorial includes simulation and sensitivity analysis showcases of small and large molecules with and without target‐mediated drug disposition.

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Predictive modeling of aspirin‐triggered resolvin D1 pharmacokinetics for the study of Sjögren's syndrome

Yellepeddi

Baker

2019

Clinical & Exp Dental Res

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Objectives Sjögren's syndrome (SS) is an autoimmune disease that causes chronic inflammation of the salivary glands leading to secretory dysfunction. Previous studies demonstrated that aspirin‐triggered resolvin D1 (AT‐RvD1) reduces inflammation and restores tissue integrity in salivary glands. Specifically, progression of SS‐like features in NOD/ShiLtJ mice can be systemically halted using AT‐RvD1 prior or after disease onset to downregulate proinflammatory cytokines, upregulate anti‐inflammatory molecules, and restore saliva production. Therefore, the goal of this paper was to create a physiologically based pharmacokinetic (PBPK) model to offer a reasonable starting point for required total AT‐RvD1 dosage to be administered in future mice and humans thereby eliminating the need for excessive use of animals and humans in preclinical and clinical trials, respectively. Likewise, PBPK modeling was employed to increase the range of testable scenarios for elucidating the mechanisms under consideration. Materials and methods Pharmacokinetics following intravenous administration of a 0.1 mg/kg dose of AT‐RvD1 in NOD/ShiLtJ were predicted in both plasma and saliva using PBPK modeling with PK‐Sim® and MoBi® Version 7.4 software. Results The model provides high‐value pathways for future validation via in vivo studies in NOD/ShiLtJ to corroborate the findings themselves while also establishing this method as a means to better target drug development and clinical study design. Conclusions Clinical and basic research would benefit from knowledge of the potential offered by computer modeling. Specifically, short‐term utility of these pharmacokinetic modeling findings involves improved targeting of in vivo studies as well as longer term prospects for drug development and/or better designs for clinical trials.

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Development and validation of a physiology-based model for the prediction of pharmacokinetics/toxicokinetics in rabbits

Cited by 20 publications

References 53 publications

A workflow to build PBTK models for novel species

A workflow to build PBTK models for novel species

ATLAS mPBPK: A MATLAB‐Based Tool for Modeling and Simulation of Minimal Physiologically‐Based Pharmacokinetic Models

Predictive modeling of aspirin‐triggered resolvin D1 pharmacokinetics for the study of Sjögren's syndrome

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