Title

How multi-organ microdevices can help foster drug development

Authors

Authors

M. B. Esch; A. S. T. Smith; J. M. Prot; C. Oleaga; J. J. Hickman;M. L. Shuler

Comments

Authors: contact us about adding a copy of your work at STARS@ucf.edu

Abbreviated Journal Title

Adv. Drug Deliv. Rev.

Keywords

Multi-organ microdevices; Body-on-a-chip; Microphysiological systems; MPS; Micro-cell culture analogs of PBPKs; mu CCAs; CELL-CULTURE ANALOG; ON-A-CHIP; PLURIPOTENT STEM-CELLS; MEDIATED; MULTIDRUG-RESISTANCE; HUMAN SKELETAL-MUSCLE; IN-VITRO; DEFINED SYSTEM; COCULTURE SYSTEM; INTESTINAL-ABSORPTION; NAPHTHALENE TOXICITY; Pharmacology & Pharmacy

Abstract

Multi-organ microdevices can mimic tissue-tissue interactions that occur as a result of metabolite travel from one tissue to other tissues in vitro. These systems are capable of simulating human metabolism, including the conversion of a pro-drug to its effective metabolite as well as its subsequent therapeutic actions and toxic side effects. Since tissue-tissue interactions in the human body can play a significant role in determining the success of new pharmaceuticals, the development and use of multi-organ microdevices present an opportunity to improve the drug development process. The devices have the potential to predict potential toxic side effects with higher accuracy before a drug enters the expensive phase of clinical trials as well as to estimate efficacy and dose response. Multi-organ microdevices also have the potential to aid in the development of new therapeutic strategies by providing a platform for testing in the context of human metabolism (as opposed to animal models). Further, when operated with human biopsy samples, the devices could be a gateway for the development of individualized medicine. Here we review studies in which multi-organ microdevices have been developed and used in a ways that demonstrate how the devices' capabilities can present unique opportunities for the study of drug action. We will also discuss challenges that are inherent in the development of multiorgan microdevices. Among these are how to design the devices, and how to create devices that mimic the human metabolism with high authenticity. Since single organ devices are testing platforms for tissues that can later be combined with other tissues within multi-organ devices, we will also mention single organ devices where appropriate in the discussion. (C) 2014 Elsevier B.V. All rights reserved.

Journal Title

Advanced Drug Delivery Reviews

Volume

69

Publication Date

1-1-2014

Document Type

Review

Language

English

First Page

158

Last Page

169

WOS Identifier

WOS:000336713500013

ISSN

0169-409X

Share

COinS