Paul A Wabnitz1, David Mitchell, David A M Wabnitz. 1. Department of Discovery Technologies, Pfizer Inc, Global Research and Development, Ann Arbor, Michigan, USA. paul.wabnitz@pfizer.com
Abstract
PURPOSE: The use of in vitro and in vivo models using both rodent and non-rodent species plays an important role with regard to metabolism during the drug development process. In this study, we compared the metabolism of a MEK inhibitor (CI-1040) using in vitro and in vivo models with that observed in a cancer patient. METHODS: Radiolabeled CI-1040 was assessed for metabolism using rat and monkey liver microsomes and hepatocytes, as well as in Wistar rats and cynomolgus monkeys via oral administration. Human bile and plasma samples were obtained immediately after administration of CI-1040 to a patient with advanced colon cancer. A combination of HPLC-radiochromatography (HPLC-RAM), LC/MS and LC/MS/MS experiments were used to analyze all resulting metabolites. Unlabeled CI-1040 was administered (100 mg/day, QD) for 15 days to a patient suffering from colon cancer. Bile was collected by the insertion of a T-tube directly into the bile duct over a 14-h period. Metabolites were also monitored in the patient's plasma. RESULTS: Analysis of the metabolites in all species using in vitro and animal models demonstrated that CI-1040 undergoes extensive oxidative metabolism (14 metabolites identified) with subsequent glucuronidation of the hydroxylated metabolites. Metabolites were predominantly excreted through the bile in the animal models. CONCLUSIONS: Overall, the in vitro and animal models in combination provided comprehensive coverage for all metabolites observed in human bile and plasma. In conclusion, the results obtained in this study demonstrate the utility of conducting investigations across species in order to gain complete coverage for successfully predicting human metabolites of new compounds in development.
PURPOSE: The use of in vitro and in vivo models using both rodent and non-rodent species plays an important role with regard to metabolism during the drug development process. In this study, we compared the metabolism of a MEK inhibitor (CI-1040) using in vitro and in vivo models with that observed in a cancerpatient. METHODS: Radiolabeled CI-1040 was assessed for metabolism using rat and monkey liver microsomes and hepatocytes, as well as in Wistar rats and cynomolgus monkeys via oral administration. Human bile and plasma samples were obtained immediately after administration of CI-1040 to a patient with advanced colon cancer. A combination of HPLC-radiochromatography (HPLC-RAM), LC/MS and LC/MS/MS experiments were used to analyze all resulting metabolites. Unlabeled CI-1040 was administered (100 mg/day, QD) for 15 days to a patient suffering from colon cancer. Bile was collected by the insertion of a T-tube directly into the bile duct over a 14-h period. Metabolites were also monitored in the patient's plasma. RESULTS: Analysis of the metabolites in all species using in vitro and animal models demonstrated that CI-1040 undergoes extensive oxidative metabolism (14 metabolites identified) with subsequent glucuronidation of the hydroxylated metabolites. Metabolites were predominantly excreted through the bile in the animal models. CONCLUSIONS: Overall, the in vitro and animal models in combination provided comprehensive coverage for all metabolites observed in human bile and plasma. In conclusion, the results obtained in this study demonstrate the utility of conducting investigations across species in order to gain complete coverage for successfully predicting human metabolites of new compounds in development.
Authors: Kenneth D Rice; Naing Aay; Neel K Anand; Charles M Blazey; Owen J Bowles; Joerg Bussenius; Simona Costanzo; Jeffry K Curtis; Steven C Defina; Larisa Dubenko; Stefan Engst; Anagha A Joshi; Abigail R Kennedy; Angie I Kim; Elena S Koltun; Julie C Lougheed; Jean-Claire L Manalo; Jean-Francois Martini; John M Nuss; Csaba J Peto; Tsze H Tsang; Peiwen Yu; Stuart Johnston Journal: ACS Med Chem Lett Date: 2012-04-09 Impact factor: 4.345