Since the introduction of titanium root-form dental implant in 60’s, it has become a widely used treatment modality in rehabilitation of completely or partially edentulous patients. However, clinicians still face the failure of implant treatment or its complication, such as progressive marginal bone loss, recession of marginal mucosa, or absence of osseointegration, inspite of its reported high success and survival rates in the literatures. In late 90’s, the application of biomimetic modification has been introduced to overcome the problems because of the advances in the understanding of the biology of bone healing process at molecular level. However, there is only marginal success in this field of research after a decade of efforts. One of the obstacles to the success is lack of an efficient and controllable coating methodology to achieve an biologically active surface with diverse function required for the healing process of surrounding tissues. In this study, we identified small adaptor peptides with titanium-binding property with a powerful screening methodology, phage display system. By five rounds of biopanning on Ti-6Al-4V discs, we isolated a clone of phage PT3 with high affinity to the surface of titanium, as verified by ELISA. We also conjugated PT3 at the amino terminus of hBMP-2 and expressed the fusion protein in E.coli. The identity of expressed protein was confirmed with mass spectrophotometry. It was then refolded and purified for further application in evaluation of the effect of immobilized growth factors on the healing process. This novel strategy may offer us a clinically efficient and easy-to-apply coating method in implant treatment.