Issue 11, 2010

Extensive adipogenic and osteogenic differentiation of patterned human mesenchymal stem cells in a microfluidic device

Abstract

Microtechnology offers great prospects for cellular research by enabling controlled experimental conditions that cannot be achieved by traditional methods. This study demonstrates the use of a microfluidic platform for long-term cultivation (3 weeks) of human mesenchymal stem-like cells (MSCs), a cell population of high interest for tissue engineering. The typical high motility of the MSCs required a strategy for preventing cells from inhabiting the feeding channels and thus interfere with a steady perfusion of medium to the cell cultivation chamber. Hence, a straightforward and long-term patterning method was developed and implemented for reliable cell positioning within the device. This method was based on the modification of a polystyrene substrate into cell supportive and non-supportive regions by the use of selective oxygen plasma treatment and the triblock copolymer Pluronic. Also, a novel and size-effective “flip-chip” set-up for operating the devices was invented. Successful and reproducible adipogenic and osteogenic differentiation of MSCs in the device was demonstrated, verifying that an adequate long-term microfluidic cultivation environment was obtained. Strengths of the experimental protocol include ease of fabrication and maintenance (gravity driven), good cell performance (viability/differentiation), as well as the possibility of exposing the culture to heterogeneous laminar flow for experimental purposes.

Graphical abstract: Extensive adipogenic and osteogenic differentiation of patterned human mesenchymal stem cells in a microfluidic device

Supplementary files

Article information

Article type
Paper
Submitted
18 Dec 2009
Accepted
12 Feb 2010
First published
09 Mar 2010

Lab Chip, 2010,10, 1401-1409

Extensive adipogenic and osteogenic differentiation of patterned human mesenchymal stem cells in a microfluidic device

E. Tenstad, A. Tourovskaia, A. Folch, O. Myklebost and E. Rian, Lab Chip, 2010, 10, 1401 DOI: 10.1039/B926738G

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