Microfluidic device platform for T cell fate analysis (TECH2P.907)

Abstract

Abstract Microfluidic systems have enormous potential as investigational devices in biomedical research, in particular immunology. Microfluidic devices can be fabricated with the precise regulation of any number of parameters including controlled surface chemistries, geometrical dimensions, signal input and output and timing. The adjustable nature of microfluidic devices makes them an ideal platform to recreate cellular microenvironments for studying cell-cell interactions, migration, antibody and cytokine production, and differentiation in vitro. Investigations with customized microfluidic devices have the potential for elucidating the mechanism behind T lymphocyte commitment to either the αβ or γδ lineage. Both types of T cells arise from immature CD4-CD8- precursors in the thymus but diverge during development. Recent publications indicate that γδ T cell receptor (TCR) works in concert with ligand to direct progenitors to the γδ fate. We propose to develop a microfluidic device in which immature T lymphocytes can migrate through a thymus-like microenvironment allowing for αβ or γδ lineage commitment. As of yet, the microfluidic device fabrication protocol has been developed and preliminary cell culture experiments with the commonly used murine stromal cell line OP9 have success. Such a device would allow for analysis of specific developmental points in T cell development.