316L stainless steel with excellent biocompatibility has been investigated by many researches. It is due to its passive oxide film. The surface characteristics of 316L stainless steel implant, such as pore sizes/roughness, are related to initial cell behaviors and osseo/osetointegration. However, the surface design of dental implant for enhancing the rate and result of osseo/osetointegration remains unknown. The purpose of this study is to investigate the effects of the various 316L stainless steel oxide thicknesses and pore sizes/roughness on the initial attachment and proliferation of the osteoblast-like cell (MG-63) based on the above investigation, it is believed that optimal pore sizes/roughness will be promoted the osseo/osetointegration. In the present study, electrochemistry process was performed as surface treatment of 316L stainless steel implant. Dichromium trioxide (Cr2O3) was formed on 316L stainless steel implant surface after anode treatment. Due micro-nano porous oxide structure was formed by anodization treatment. As mentioned above, physical properties, chemical properties as well as biocompatibility of 316L stainless steel implant with and without electrochemical surface treatments were analyzed clearly. In addition, biocompatibility of 316L stainless steel implant with and without surface treatments was performed by cell cultures. MTT test and cell counting is used to investigate the cell attachment and proliferation. Furthermore, mechanism of bone healing on micro-nanoporous implant surface and interaction were also discussed clearly. It is believed that it is helpful to realize the osseointegraion mechanism.