Population pharmacokinetics of gemcitabine and its metabolite in japanese cancer patients: Impact of genetic polymorphisms

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

Research output: Contribution to journalArticlepeer-review

51 Scopus citations

Abstract

Background and Objective: Gemcitabine (20,20-difluorodeoxycytidine) is an anticancer drug, which is effective against solid tumours, including non-small-cell lung cancer and pancreatic cancer. After gemcitabine is transported into cells by equilibrative and concentrative nucleoside transporters, it is phosphorylated by deoxycytidine kinase (DCK) and further phosphorylated to its active diphosphorylated and triphosphorylated forms. Gemcitabine is rapidly metabolized by cytidine deaminase (CDA) to an inactive metabolite, 20,20-difluorodeoxyuridine (dFdU), which is excreted into the urine. Toxicities of gemcitabine are generally mild, but unpredictable severe toxicities such as myelosuppression and interstitial pneumonia are occasionally encountered. The aim of this study was to determine the factors, including genetic polymorphisms of CDA, DCK and solute carrier family 29A1 (SLC29A1 [hENT1]), that alter the pharmacokinetics of gemcitabine in Japanese cancer patients. Patients and Methods: 250 Japanese cancer patients who received 30-minute intravenous infusions of gemcitabine at 800 or 1000mg/m2 in the period between September 2002 and July 2004 were recruited for this study. However, four patients were excluded from the final model built in this study because they showed bimodal concentration-time curves. Two patients who experienced gemcitabine-derived life-threatening toxicities in October 2006 and January 2008 were added to this analysis. One of these patients received 30-minute intravenous infusions of gemcitabine at 454mg/m2 instead of the usual dose (1000mg/m2). Plasma concentrations of gemcitabine and dFdU were measured by high-performance liquid chromatography-photodiode array/mass spectrometry. In total, 1973 and 1975 plasma concentrations of gemcitabine and dFdU, respectively, were used to build population pharmacokinetic models using nonlinear mixed-effects modelling software (NONMEM version V level 1.1). Results and Discussion: Two-compartment models fitted well to plasma concentration-time curves for both gemcitabine and dFdU. Major contributing factors for gemcitabine clearance were genetic polymorphisms of CDA, including homozygous CDA*3 [208G>A (Ala70Thr)] (64% decrease), heterozygous*3 (17% decrease) and CDA -31delC (an approximate 7% increase per deletion), which has a strong association with CDA*2 [79A>C (Lys27Gln)], and coadministered S-1, an oral, multicomponent anti-cancer drug mixture consisting of tegafur, gimeracil and oteracil (an approximate 19% increase). The estimated contribution of homozygous CDA*3 to gemcitabine clearance provides an explanation for the life-threatening severe adverse reactions, including grade 4 neutropenia observed in three Japanese patients with homozygous CDA*3. Genetic polymorphisms of DCK and SLC29A1 (hENT1) had no significant correlation with gemcitabine pharmacokinetic parameters. Aging and increased serum creatinine levels correlated with decreased dFdU clearance. Conclusion: A population pharmacokinetic model that included CDA genotypes as a covariate for gemcitabine and dFdU in Japanese cancer patients was successfully constructed. The model confirms the clinical importance of the CDA*3 genotype.

Original languageEnglish
Pages (from-to)549-558
Number of pages10
JournalClinical Pharmacokinetics
Volume49
Issue number8
DOIs
StatePublished - 2010
Externally publishedYes

Keywords

  • antineoplastics
  • gemcitabinepharmacokinetics
  • genetic-polymorphism
  • genotype
  • metabolites
  • pharmacokinetic-modelling
  • pharmacokinetics
  • population-pharmacokinetics

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