Literature DB >> 30069744

Physiologically-based pharmacokinetic and pharmacodynamic models for gemcitabine and birinapant in pancreatic cancer xenografts.

Xu Zhu1, Sheryl Trueman1, Robert M Straubinger1, William J Jusko2,3.   

Abstract

The anticancer effects of combined gemcitabine and birinapant were demonstrated as synergistic in PANC-1 cells in vitro. In this study, pharmacokinetic information derived from experiments and the literature was utilized to develop full physiologically-based pharmacokinetic (PBPK) models that characterize individual drugs. The predicted intra-tumor drug concentrations were used as the driving force within a linked PBPK/PD model for treatment-mediated changes in tumor volume in a xenograft mouse model. The efficacy of the drug combination in vivo was evaluated mathematically as exhibiting additivity. The network model developed for drug effects in the in vitro cell cultures was applied successfully to link the in vivo tumor drug concentrations with tumor growth inhibition, incorporating more mechanistic features and accounting for disparate drug interaction outcomes in vitro and in vivo.

Entities:  

Keywords:  Birinapant; Drug combination; Gemcitabine; Pancreatic cancer xenografts; Pharmacodynamics; Physiologically-based pharmacokinetic model

Mesh:

Substances:

Year:  2018        PMID: 30069744      PMCID: PMC6160358          DOI: 10.1007/s10928-018-9603-z

Source DB:  PubMed          Journal:  J Pharmacokinet Pharmacodyn        ISSN: 1567-567X            Impact factor:   2.745


  29 in total

1.  Population pharmacokinetics of gemcitabine and its metabolite in Japanese cancer patients: impact of genetic polymorphisms.

Authors:  Emiko Sugiyama; Nahoko Kaniwa; Su-Ryang Kim; Ryuichi Hasegawa; Yoshiro Saito; Hideki Ueno; Takuji Okusaka; Masafumi Ikeda; Chigusa Morizane; Shunsuke Kondo; Noboru Yamamoto; Tomohide Tamura; Junji Furuse; Hiroshi Ishii; Teruhiko Yoshida; Nagahiro Saijo; Jun-Ichi Sawada
Journal:  Clin Pharmacokinet       Date:  2010-08       Impact factor: 6.447

2.  Dose-finding and pharmacokinetic study of cisplatin, gemcitabine, and SU5416 in patients with solid tumors.

Authors:  Bart C Kuenen; Lee Rosen; Egbert F Smit; Mandy R N Parson; Marcel Levi; Rita Ruijter; Holger Huisman; Marc A Kedde; Paul Noordhuis; Wim J F van der Vijgh; Godefridus J Peters; Gillian F Cropp; Paul Scigalla; Klaus Hoekman; Herbert M Pinedo; Giuseppe Giaccone
Journal:  J Clin Oncol       Date:  2002-03-15       Impact factor: 44.544

3.  Physiologically based pharmacokinetic models for everolimus and sorafenib in mice.

Authors:  Dipti K Pawaskar; Robert M Straubinger; Gerald J Fetterly; Bonnie H Hylander; Elizabeth A Repasky; Wen W Ma; William J Jusko
Journal:  Cancer Chemother Pharmacol       Date:  2013-03-03       Impact factor: 3.333

Review 4.  Drug resistance and the solid tumor microenvironment.

Authors:  Olivier Trédan; Carlos M Galmarini; Krupa Patel; Ian F Tannock
Journal:  J Natl Cancer Inst       Date:  2007-09-25       Impact factor: 13.506

5.  Lysosomal sequestration (trapping) of lipophilic amine (cationic amphiphilic) drugs in immortalized human hepatocytes (Fa2N-4 cells).

Authors:  Faraz Kazmi; Tiffini Hensley; Chad Pope; Ryan S Funk; Greg J Loewen; David B Buckley; Andrew Parkinson
Journal:  Drug Metab Dispos       Date:  2013-02-01       Impact factor: 3.922

6.  A Phase I Study of the SMAC-Mimetic Birinapant in Adults with Refractory Solid Tumors or Lymphoma.

Authors:  Ravi K Amaravadi; Russell J Schilder; Lainie P Martin; Myron Levin; Martin A Graham; David E Weng; Alex A Adjei
Journal:  Mol Cancer Ther       Date:  2015-09-02       Impact factor: 6.261

7.  Metabolism and disposition of gemcitabine, and oncolytic deoxycytidine analog, in mice, rats, and dogs.

Authors:  L A Shipley; T J Brown; J D Cornpropst; M Hamilton; W D Daniels; H W Culp
Journal:  Drug Metab Dispos       Date:  1992 Nov-Dec       Impact factor: 3.922

8.  Physiologically based pharmacokinetic model for specific and nonspecific monoclonal antibodies and fragments in normal tissues and human tumor xenografts in nude mice.

Authors:  L T Baxter; H Zhu; D G Mackensen; R K Jain
Journal:  Cancer Res       Date:  1994-03-15       Impact factor: 12.701

9.  Experimental in vivo and in vitro treatment with a new histone deacetylase inhibitor belinostat inhibits the growth of pancreatic cancer.

Authors:  Dmitriy I Dovzhanskiy; Stefanie M Arnold; Thilo Hackert; Ina Oehme; Olaf Witt; Klaus Felix; Nathalia Giese; Jens Werner
Journal:  BMC Cancer       Date:  2012-06-08       Impact factor: 4.430

10.  High cytidine deaminase expression in the liver provides sanctuary for cancer cells from decitabine treatment effects.

Authors:  Quteba Ebrahem; Reda Z Mahfouz; Kwok Peng Ng; Yogen Saunthararajah
Journal:  Oncotarget       Date:  2012-10
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  3 in total

1.  Hyperthermia Enhances Efficacy of Chemotherapeutic Agents in Pancreatic Cancer Cell Lines.

Authors:  Costanza E Maurici; Robin Colenbier; Britta Wylleman; Luigi Brancato; Eke van Zwol; Johan Van den Bossche; Jean-Pierre Timmermans; Elisa Giovannetti; Marina G M C Mori da Cunha; Johannes Bogers
Journal:  Biomolecules       Date:  2022-04-29

2.  EWSR1-WT1 Target Genes and Therapeutic Options Identified in a Novel DSRCT In Vitro Model.

Authors:  Margit Bleijs; Corine Pleijte; Sem Engels; Femke Ringnalda; Friederike Meyer-Wentrup; Marc van de Wetering; Hans Clevers
Journal:  Cancers (Basel)       Date:  2021-12-02       Impact factor: 6.639

3.  Mechanistic Multiscale Pharmacokinetic Model for the Anticancer Drug 2',2'-difluorodeoxycytidine (Gemcitabine) in Pancreatic Cancer.

Authors:  Maria Garcia-Cremades; Nicola Melillo; Iñaki F Troconiz; Paolo Magni
Journal:  Clin Transl Sci       Date:  2020-03-03       Impact factor: 4.689
  3 in total

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