3-D microgels ‘on-demand’ offer new potential for cell research

Posted: Published on February 27th, 2014

This post was added by Dr P. Richardson

PUBLIC RELEASE DATE:

26-Feb-2014

Contact: Erin Vollick comm.ibbme@utoronto.ca 416-946-8019 University of Toronto

Stars, diamonds, circles.

Rather than your average bowl of Lucky Charms, these are three-dimensional cell cultures generated by an exciting new digital microfluidics platform, the results of which have been published in Nature Communications this week by researchers at the University of Toronto. The tool, which can be used to study cells in cost-efficient, three-dimensional microgels, may hold the key to personalized medicine applications in the future.

"We already know that the microenvironment can greatly influence cell fate," says Irwin A. Eydelnant, recent doctoral graduate from IBBME and first author of the publication. "The important part of this study is that we've developed a tool that will allow us to investigate the sensitivity of cells to their 3D environment."

"Everyone wants to do three-dimensional (3D) cell culture," explains Aaron Wheeler, Professor and Canada Research Chair in Bioanalytical Chemistry at the Institute of Biomaterials & Biomedical Engineering (IBBME), the Department of Chemistry, and the Donnelly Centre for Cellular and Biomolecular Research (DCCBR) at the University of Toronto. "Cells grown in this manner share much more in common with living systems than the standard two-dimensional (2D) cell culture format," says Wheeler, corresponding author of the study.

But more naturalistic, 3D cell cultures are a challenge to grow. "The reagents are expensive, the materials are inconvenient for automation, and 3D matrices break down upon repeated handling," explains Wheeler, who was named an Inventor of the Year by the University of Toronto in 2012.

Eydelnant was able to address these difficulties by adapting a digital microfluidics platform first created in the Wheeler lab. Cells, caught up in a hydrogel material, are gently flowed across a small field that, on a screen, looks much like a tiny chessboard. The cells are strategically manipulated by a small electric field across a cutout shape on the top plate of the system, made from indium in oxide, and become fixed.

"When we grew kidney cells in these microgels, the cultures formed hollow sphere structures resembling primitive kidneys within four or five days," Eydelnant claims.

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3-D microgels 'on-demand' offer new potential for cell research

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