Development of Rat Duodenal Monolayer Model with Effective Barrier Function from Rat Organoids for ADME Assay

Overview

Journal Sci Rep

Specialty Science

Date 2023 Jul 26

PMID 37495742

Authors

Kai Tanaka

Shigeto Kawai

Etsuko Fujii

Masumi Yano

Takashi Miyayama

Kiyotaka Nakano

Kimio Terao

Masami Suzuki

Affiliations

Soon will be listed here.

Abstract

The in-depth analysis of the ADME profiles of drug candidates using in vitro models is essential for drug development since a drug's exposure in humans depends on its ADME properties. In contrast to efforts in developing human in vitro absorption models, only a limited number of studies have explored models using rats, the most frequently used species in in vivo DMPK studies. In this study, we developed a monolayer model with an effective barrier function for ADME assays using rat duodenal organoids as a cell source. At first, we developed rat duodenal organoids according to a previous report, but they were not able to generate a confluent monolayer. Therefore, we modified organoid culture protocols and developed cyst-enriched organoids; these strongly promoted the formation of a confluent monolayer. Furthermore, adding valproic acid to the culture accelerated the differentiation of the monolayer, which possessed an effective barrier function and apicobasal cell polarity. Drug transporter P-gp function as well as CYP3A activity and nuclear receptor function were confirmed in the model. We expect our novel monolayer model to be a useful tool for elucidating drug absorption processes in detail, enabling the development of highly absorbable drugs.

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