Simulation of Chemotractant Gradients in Microfluidic Channels to Study Cell Migration Mechanism in silico
Paper in proceedings, 2012

Cell migration of endothelial cells along gradients is an important process in vivo and an interesting target for cancer therapeutics. Microfluidics offer very powerful tools to study such migration processes in detail in the lab. In order to optimize microfluidic systems multiphysics simulations are very well suited. In this study, we describe a model to simulate molecular gradients in a diffusion based microfluidic gradient generator and how a cell senses these gradients via cell receptors. The results show the importance of incorporating the binding reaction into the model and that there is a large difference between the molecular gradient in solution and the gradient sensed by the cell. The approach presented here allows capturing of the whole process from gradient formation with a microfluidic channel to binding of molecules to cell receptors and allow a better prediction of parameters for cell experiments.

molecular gradient

VEGF

Cell-receptor interaction

Cell migration

microfluidic

Author

Patric Wallin

Chalmers, Applied Physics, Biological Physics

Elin Bernson

Chalmers, Applied Physics, Biological Physics

Julie Gold

Chalmers, Applied Physics, Biological Physics

Comsol User meeting 2012 Milan

Subject Categories

Cell Biology

Other Physics Topics

Biophysics

Organic Chemistry

More information

Created

10/6/2017