A novel single layer microfluidic device for dynamic stimulation, culture and imaging of mammalian cells

Abstract

AbstractThe possibility to tightly control the cellular microenvironment within microfluidic devices represents an important step forward precision analysis of cellular phenotypes in vitro. In particular, microfluidic platforms that allow both long-term mammalian cell culture and dynamic modulation of the culture environment can support quantitative studies of cells’ responses to drugs. Here, we report the design and testing of a novel microfluidic device of easy production (single Polydimethylsiloxane layer), which integrates a micromixer with vacuum-assisted cell loading for long-term mammalian cell culture and dynamic mixing of 4 different culture media. Finite element modelling was used to predict the flow rates and device dimensions to achieve diffusion-based fluid mixing. The device showed efficient mixing and dynamic exchange of media in the cell trapping chambers. This work represents the first attempt to integrate single layer microfluidic mixing devices with vacuum-assisted cell loading systems for mammalian cell culture and dynamic stimulation.