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The innate immune response is a complicated process that involves a coordinated effort by many cell populations; however, the role of these multicellular interactions in driving immune cell function is unclear. Currently, immune cell function is studied in one of two ways: using in vitro devices in which a single cell type’s function is studied in response to an activating signal or using an in vivo model whose inherent complexity makes it difficult to tease apart the role of specific cellular interactions on immune cell function. Therefore, a need exists for in vitro devices that recapitulate important aspects of the infectious microenvironment to study immune cell function. Our group is designing new biologically inspired in vitro models that incorporate multicellular interactions and physiologically relevant structures to recapitulate the infectious microenvironment. We are then using these models to investigate the role of cell-cell interactions on immune cell migration and antimicrobial function in response to a variety of infections.

New subsets of immune cells, such as Myeloid Derived Suppressor Cells, have been identified using single cell genomic techniques. These cells are most prevalent in cancer patients, but they can also have an important role in infection. Little is known about how these cells migrate to a site of infection, become activated by invading pathogens, or interact with other cells of the immune system. Our group is investigating the modes in which these immune cell subsets migrate and how they function in an infectious environment.