Stepwise and Programmable Cell Differentiation Pathways of Controlled Functional Biointerfaces.

An advanced control of biomaterial surfaces was created to enable the stepwise and switchable activities of the immobilized growth factor (GF) proteins for a programmed manipulation over cell differentiation pathways. The GF protein was immobilized on an advanced vapor-based coating of poly[(4-2-amide-2'-amine-dithiobisethyl- p -xylylene)- co -( p -xylylene)], and the equipped disulfide exchange mechanism of the coating enables the detachment and/or the displacement of the previously installed GF to reinstall a second GF protein. In this study, the controlled immobilization and displacement of the fibroblast growth factor (FGF-2) and bone morphogenetic protein (BMP-2) were demonstrated on cell culture substrates, and the resulting surfaces provided a programmable induction of cellular responses in proliferation and osteogenesis toward the cultured murine preosteoblasts (MC3T3-E1). A depreciated or stopped activity of the previously induced biological function, i.e., proliferation or osteogenesis, was found for MC3T3-E1 on the modified surface after the cleavage of the corresponding GF. In addition, with the approach to devise the displacement and reinstallation of FGF-2/BMP-2 proteins, a combined induction of proliferation and osteogenesis can be initiated in a timed latency to resolve programmable biological activities.