Degree of early integration of titanium alloy implants into bone is an important predictor of long term implant success in arthroplasty. The correlation between observations on early cell adhesion and the ability of modified surfaces to affect osseointegration of implants in in vivo models is unclear. We hypothesised that observation of increased focal adhesion complexes in early cultures of osteoblasts would correlate with increased osseointegration of treated implants in an animal model. Longer term culture of rat osteoblasts for alkaline phosphatase activity indicated that cells cultured on the 9V treated surfaces were displaying greater alkaline phosphatase activity at 14 days. Bone nodule formation at 28 days demonstrated a trend towards smaller area of bone nodules on the surfaces treated at 9V then those treated at 3V and 5V. A rat model was employed for testing mechanical push-out strength of experimental implants and demonstrated a trend towards increased yield strength of the bone-implant interface for implants treated at 3V180s and 5V180s. Histomorphometry was performed and no statistically significant differences in percentage area of contact with mineralised bone matrix were seen, although there was a trend for greater mineralised matrix contact on the polished and 9V180s treated implants. Previous experiments demonstrated cells on the 9V treated surfaces were well spread and had significantly increased size and number of focal adhesions. This was regarded as indicating more successful cell adhesion. The above results demonstrate that this early trend disappeared in longer term culture did not persist in experiments in an animal model.

Background

Uncemented implants are an important part of the arthroplasty armamentarium. Risk of aseptic loosening and failure of these components is related to initial osseointegration - the formation of a seamless bone-implant interface without interposition of fibrous tissue.