Contributions of the Microbiome to Intestinal Inflammation in a Gut-on-a-chip

Overview

Journal Nano Converg

Specialty Biotechnology

Date 2022 Feb 8

PMID 35133522

Authors

Min Seo Jeon

Yoon Young Choi

Sung Jun Mo

Jang Ho Ha

Young Seo Lee

Hee Uk Lee

Soo Dong Park

Jae-Jung Shim

Jung-Lyoul Lee

Bong Geun Chung

Affiliations

Soon will be listed here.

Abstract

The intestinal microbiome affects a number of biological functions of the organism. Although the animal model is a powerful tool to study the relationship between the host and microbe, a physiologically relevant in vitro human intestinal system has still unmet needs. Thus, the establishment of an in vitro living cell-based system of the intestine that can mimic the mechanical, structural, absorptive, transport and pathophysiological properties of the human intestinal environment along with its commensal bacterial strains can promote pharmaceutical development and potentially replace animal testing. In this paper, we present a microfluidic-based gut model which allows co-culture of human and microbial cells to mimic the gastrointestinal structure. The gut microenvironment is recreated by flowing fluid at a low rate (21 μL/h) over the microchannels. Under these conditions, we demonstrated the capability of gut-on-a-chip to recapitulate in vivo relevance epithelial cell differentiation including highly polarized epithelium, mucus secretion, and tight membrane integrity. Additionally, we observed that the co-culture of damaged epithelial layer with the probiotics resulted in a substantial responded recovery of barrier function without bacterial overgrowth in a gut-on-a-chip. Therefore, this gut-on-a-chip could promote explorations interaction with host between microbe and provide the insights into questions of fundamental research linking the intestinal microbiome to human health and disease.

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