Effects of functional groups and soluble matrices in fish otolith on calcium carbonate mineralization

Effects of surface functional groups on proliferation and biofunction of Schwann cells

Scaffolds in tissue engineering should be rationally designed to become an adhesion substrate friendly to cells. Schwann cells play an important role in nerve regeneration and repair. Previous studies have suggested that surface chemical groups have effect on many types of cells. However, there have hitherto been few reports on Schwann cells. In this study, we investigated cell adhesion, survival, proliferation, and neurotrophic actions of Schwann cells cultured on glass coverslips modified with different chemical groups, including methyl, carboxyl, amino, hydroxyl, mercapto, and sulfonic groups. Schwann cells on amino and carboxyl surfaces had higher attachment rate, presenting good morphology, high proliferation, and strong neurotrophic functions, while on methyl surfaces, few cells can survive, cells shrunk into round shape, exhibiting poor proliferation and weak neurotrophic functions. Growth of cells on other groups was between methyl and amino, carboxyl, and had little difference among them. Our data indicated that chemical groups can regulate behavior of Schwann cells, indicating a way to design new scaffolds for peripheral nerve regeneration.

Two competitive nucleation mechanisms of calcium carbonate biomineralization in response to surface functionality in low calcium ion concentration solution

Four self-assembled monolayer surfaces terminated with –COOH, –OH, –NH₂ and –CH₃ functional groups are used to direct the biomineralization processes of calcium carbonate (CaCO₃) in low Ca²⁺ concentration, and the mechanism of nucleation and initial crystallization within 12 h was further explored. On −COOH surface, nucleation occurs mainly via ion aggregation mechanism while prenucleation ions clusters may be also involved. On −OH and −NH₂ surfaces, however, nucleation forms via calcium carbonate clusters, which aggregate in solution and then are adsorbed onto surfaces following with nucleation of amorphous calcium carbonate (ACC). Furthermore, strongly negative-charged −COOH surface facilitates the direct formation of calcites, and the −OH and −NH₂ surfaces determine the formation of vaterites with preferred crystalline orientations. Neither ACC nor crystalline CaCO₃ is observed on −CH₃ surface. Our findings present a valuable model to understand the CaCO₃ biomineralization pathway in natural system where functional groups composition plays a determining role during calcium carbonate crystallization.