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Volume-constrained microcontainers enable myoepithelial functional differentiation in highly parallel mammary organoid culture

Michael E. Todhunter, Masaru Miyano, Divya S. Moolamalla, Aleksandr Filippov, Rosalyn W. Sayaman, Mark A. LaBarge

2021iScience11 citationsDOIOpen Access PDF

Abstract

A long-standing constraint on organoid culture is the need to add exogenous substances to provide hydrogel matrix, which limits the study of fully human or fully native organoids. This paper introduces an approach to culture reconstituted mammary organoids without the impediment of exogenous matrix. We enclose organoids in nanoliter-scale, topologically enclosed, fluid compartments surrounded by agar. Organoids cultured in these "microcontainers" appear to secrete enough extracellular matrix to yield a self-sufficient microenvironment without exogenous supplements. In microcontainers, mammary organoids exhibit contractility and a high-level, physiological, myoepithelial (MEP) behavior that has not been previously reported in reconstituted organoids. The presence of contractility suggests that microcontainers elicit MEP functional differentiation, an important milestone. Microcontainers yield thousands of substantially identical and individually trackable organoids within a single culture vessel, enabling longitudinal studies and statistically powerful experiments, such as the evaluation of small effect sizes. Microcontainers open new doors for researchers who rely on organoid models.

Topics & Concepts

OrganoidCell biologyExtracellular matrixMyoepithelial cellBiologyChemistryImmunologyImmunohistochemistry3D Printing in Biomedical ResearchCancer Cells and MetastasisPlanarian Biology and Electrostimulation
Volume-constrained microcontainers enable myoepithelial functional differentiation in highly parallel mammary organoid culture | Litcius