ENGUT was awarded the BIST Ignite Grant in March 2018.
Epithelial barriers, such as the intestinal epithelium, protect the body against external attacks. Functional in vitro models of intestinal epithelium have been pursued for a long time. They are key elements in basic research, disease modelling, drug discovery, and tissue replacing and have become prime models for adult stem cell research. By taking advantage of the self-organizing properties of intestinal stem cells, intestinal organoids have been recently established, showing cell renewal’s kinetics resembling the one found in vivo. However, the development of in vitro 3D tissue equivalents accounting for the dimensions, architecture and access to the luminal contents of the in vivo human intestinal tissue together with its self-renewal properties and cell complexity, remains a challenge.
The goal of ENGUT is to engineer intestinal epithelial tissue models that mimic physiological characteristics found in in vivo human intestinal tissue, to open up new areas of research in human intestinal diseases. The proposed models will address the in vivo intestinal epithelial cell renewal and migration, the multicell-type differentiation and the epithelial cell interactions with the underlying basement membrane while providing access to the luminal content to go beyond the state-of-the-art organoid models. To do this, we propose to develop an experimental setup that combines microfabrication techniques, tissue engineering components, recent advances in intestinal stem cell research, and cutting-edge microscopy techniques. We expect the new device to prove useful in understanding cell physiology, adult stem cell behaviour, and organ development, as well as in modelling human intestinal diseases.
Multidisciplinarity within ENGUT
The success of the ENGUT project heavily relies on the effective integration of multiple core-disciplines. The ENGUT proposal combines engineering microfabrication technologies such as photolithography and microfluidics, tissue engineering concepts (scaffolds and bioreactors), recent advances in stem cell research (organoids) and cutting-edge microscopy techniques (customized light sheet imaging) to produce artificial tissue surrogates that will go beyond current 3D in vitro models. The teams involved in ENGUT are already multidisciplinary in nature, as their members have scientific backgrounds in physics, biology and molecular biology.