Osteoblast population migration characteristics on substrates modified with immobilized adhesive peptides

Abstract

The process of cell migration is inextricably linked with the process of cell adhesion and, therefore, with cell/substrate adhesiveness. The present study adapted an under-agarose cell migration assay to quantitatively examine population migration characteristics of osteoblasts, on substrates modified with adhesive peptides, in the absence and presence of growth factors. Short-term, that is, 48 h osteoblast migration distances on substrates modified with adhesive Arg–Gly–Asp–Ser peptides were significantly ( P<0.05) less than migration distances on substrates modified with non-adhesive Arg–Asp–Gly–Ser peptides, demonstrating that osteoblast population haptokinesis was significantly decreased on substrates modified with adhesive peptides. Random motility coefficients calculated in the present study for osteoblast populations were an order of magnitude lower than a published random motility coefficient for leukocytes, proving quantitatively that, compared to leukocytes, osteoblasts migrate via haptokinesis more slowly. The 48 and 72 h osteoblast population migration differentials in the presence of an initial mass of 60 ng of basic Fibroblast Growth Factor, on substrates modified with Arg–Gly–Asp–Ser or with Arg–Asp–Gly–Ser, were larger than all other chemotactic differentials on these substrates. Quantitative investigations (such as the present study) of cell population migration characteristics on model biomaterial surfaces will become increasingly necessary as the discipline of cell/tissue engineering matures.