An Improved Scalable Hydrogel Dish for Spheroid Culture

Research in fields studying cellular response to surface tension and mechanical forces necessitate cell culture tools with tunability of substrate stiffness. We created a scalable hydrogel dish design to facilitate scaffold-free formation of multiple spheroids in a single dish. Our novel design feat...

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Bibliographic Details
Main Authors: Jonard Corpuz Valdoz, Dallin J. Jacobs, Collin G. Cribbs, Benjamin C. Johnson, Brandon M. Hemeyer, Ethan L. Dodson, Jordan A. Saunooke, Nicholas A. Franks, Peter Daniel Poulson, Seth R. Garfield, Connor J. Knight, Pam M. Van Ry
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Life
Subjects:
Online Access:https://www.mdpi.com/2075-1729/11/6/517
Description
Summary:Research in fields studying cellular response to surface tension and mechanical forces necessitate cell culture tools with tunability of substrate stiffness. We created a scalable hydrogel dish design to facilitate scaffold-free formation of multiple spheroids in a single dish. Our novel design features inner and outer walls, allowing efficient media changes and downstream experiments. The design is easily scalable, accommodating varying numbers of microwells per plate. We report that non-adherent hydrogel stiffness affects spheroid morphology and compaction. We found that spheroid morphology and viability in our hydrogel dishes were comparable to commercially available Aggrewell™800 plates, with improved tunability of surface stiffness and imaging area. Device function was demonstrated with a migration assay using two investigational inhibitors against EMT. We successfully maintained primary-derived spheroids from murine and porcine lungs in the hydrogel dish. These features increase the ability to produce highly consistent cell aggregates for biological research.
ISSN:2075-1729