Nitric oxide-generating polymers reduce platelet adhesion and smooth muscle cell proliferation.

We have developed polymeric biomaterials capable of providing localized and sustained production of nitric oxide (NO) for the prevention of thrombosis and restenosis. In the current study, we have characterized the kinetics of NO production by these materials and investigated their efficacy in reducing platelet adhesion and smooth muscle cell proliferation in vitro. Three nitric oxide donors with different half-lives were covalently incorporated into photopolymerized polyethylene glycol hydrogels. Under physiological conditions, NO was produced by these hydrogels over periods ranging from hours to months, depending upon the polymer formulation. NO production was inhibited at acidic pH, which may be useful for storage of the materials. The NO-releasing materials successfully inhibited smooth muscle cell growth in culture. Platelet adhesion to collagen-coated surfaces was also inhibited following exposure of whole blood to NO-producing hydrogels. The effects of NO production by these hydrogels on platelet adhesion and the proliferation of smooth muscle cells suggest that these materials could reduce thrombosis and restenosis following procedures such as balloon angioplasty.

Role of synthetic extracellular matrix in development of engineered dental pulp.

In cases of damaged oral tissues, traditional therapies, such as a root canal, replace the injured tissue with a synthetic material. However, while the materials currently used can offer structural replacement of the lost tissue, they are incapable of completely replacing the function of the original tissue, and often fail over time. This report describes a tissue engineering approach to dental pulp tissue replacement utilizing cultured cells seeded upon synthetic extracellular matrices. Human pulp fibroblasts were obtained and multiplied in culture. These cells were then seeded onto three different synthetic matrices: scaffolds fabricated from polyglycolic acid (PGA) fibers, a type I collagen hydrogel, and alginate in an effort to examine which matrix is most suitable for dental pulp tissue formation. In addition, methods previously developed for seeding and culturing pulp cells on PGA were optimized. Culturing cells on PGA resulted in a very high cell density tissue with significant collagen deposition. No cell proliferation was observed on alginate, and the growth of cells in collagen gels after 45 days was only moderate. These studies indicate dental pulp-like tissues can be engineered, and this may provide the first step to engineering a complete tooth.