A Microfluidic System for Mouse Embryonic Stem Cell Culture and Microenvironment Control

Moledina, Faisal

23 August 2011

The embryonic stem cell (ESC) microenvironment contains various localized physical and biochemical cues to direct cell fate. Current approaches for microenvironmental regulation rely on restricting cell behaviour to control endogenous signals such as secreted ligands. This report presents a microfluidic device that can directly manipulate the removal of autoregulatory ligands from culture and control the activation of Signal Transducer and Activator of Transcription-3 (Stat3) in ESCs. Specifically, the response of Stat3 was measured under diffusive and convective mass transfer regimes. A Brownian dynamics algorithm was also developed to simulate ligand transport and predict cellular response under these conditions. Stat3 activation under perfusion culture was found to depend on flow rate and axial distance in the flow direction. Long-term perfusion also allowed for the formation of a sustained gradient of Stat3 activation that led to selective loss of ESC pluripotency. These results demonstrate the utility of microfluidic culture for stem cell bioengineering applications.

stem cells

mathematical modelling

microfluidics

mESC self-renewal

autocrine signalling

0541

A Microfluidic System for Mouse Embryonic Stem Cell Culture and Microenvironment Control

Moledina, Faisal

23 August 2011

The embryonic stem cell (ESC) microenvironment contains various localized physical and biochemical cues to direct cell fate. Current approaches for microenvironmental regulation rely on restricting cell behaviour to control endogenous signals such as secreted ligands. This report presents a microfluidic device that can directly manipulate the removal of autoregulatory ligands from culture and control the activation of Signal Transducer and Activator of Transcription-3 (Stat3) in ESCs. Specifically, the response of Stat3 was measured under diffusive and convective mass transfer regimes. A Brownian dynamics algorithm was also developed to simulate ligand transport and predict cellular response under these conditions. Stat3 activation under perfusion culture was found to depend on flow rate and axial distance in the flow direction. Long-term perfusion also allowed for the formation of a sustained gradient of Stat3 activation that led to selective loss of ESC pluripotency. These results demonstrate the utility of microfluidic culture for stem cell bioengineering applications.

stem cells

mathematical modelling

microfluidics

mESC self-renewal

autocrine signalling

0541