Effects of substrate nanopatterning on human osteosarcoma cells (SaOs-2) behavior

Abstract

Engineering of the cellular microenvironment has become an attractive strategy to guide cellular activities such as spreading, motility, proliferation and differentiation. From a technological perspective, the physical crosstalk between a cell and its surrounding represents a design parameter that may be modulated to achieve desired osseointegration in orthopedic and dental implants. In this study we use a surface engineering approach to tap into the interaction between the cell and its surroundings in order to modulate osteogenic adhesion-dependent differentiation and bone tissue formation. The effectiveness of this approach was studied by observing the in vitro cellular behavior of human osteoblastic cells (SaOs-2) seeded on silicon substrates with different nano-scale surface patterns. Our findings suggest that substrate nanopattern geometry can differentially control early cell differentiation decisions. Interestingly, rescue of the differentiation process by supplementation of growth medium with soluble differentiation factors did not appear to compensate for the differences in the early cellular fate decisions observed on the different patterns. Critically, combining surface topography and soluble differentiation factors appeared to modulate the speed of the differentiation process and its shut down at the end of terminal differentiation. Taken together, our findings suggest that cells recognize physical nano-scale topography as an instructive signal that is integrated to fine-tune the multimodal control and guidance of cell behavior and cell fate. This information may find utility in the design of orthopedic and dental implants or innovative bio-materials for regenerative medicine.