Methods to Generate Tube Micropatterns for Epithelial Morphogenetic Analyses and Tissue Engineering.

Cells live in a highly curved and folded 3D microenvironment within the human body. Since epithelial cells in internal organs usually adopt a tubular shape, there is a need to engineer simple in vitro devices to promote this cellular configuration. The aim of these devices would be to investigate epithelial morphogenesis and cell behavior-leading to the development of more sophisticated platforms for tissue engineering and regenerative medicine. In this chapter, we first explain the need for such epithelial tubular micropatterns based on anatomical considerations and then survey methods that can be used to study different aspects of epithelial tubulogenesis. The methods examined can broadly be divided into two classes: conventional 2D microfabrication for the formation of simple epithelial tubes in substrates of different stiffness; and 3D approaches to enable the self-assembly of organoid-derived epithelial tubes in a tubular configuration. These methods demonstrate that modeling tubulogenesis in vitro with high resolution, accuracy, and reproducibility is possible

Automated brightfield morphometry of 3D organoid populations by OrganoSeg

Spheroid and organoid cultures are powerful in vitro models for biology, but size and shape diversity within the culture is largely ignored. To streamline morphometric profiling, we developed OrganoSeg, an open-source software that integrates segmentation, filtering, and analysis for archived brightfield images of 3D culture. OrganoSeg is more accurate and flexible than existing platforms, and we illustrate its potential by stratifying 5167 breast-cancer spheroid and 5743 colon and colorectal-cancer organoid morphologies. Organoid transcripts grouped by morphometric signature heterogeneity were enriched for biological processes not prominent in the original RNA sequencing data. OrganoSeg enables complete, objective quantification of brightfield phenotypes, which may give insight into the molecular and multicellular mechanisms of organoid regulation