Dental Implants have become one of the main treatment modalities for missing teeth. The successful factors include the implant design, the surface treatment, the bone quality, the surgical technique, and so on. Among these factors, the implant design is the dominant clinical factor. It’s easier to do initial insertion, decrease the torque of initial insertion, reduce the thermal injury, increase the stability, reduce the resorption of tooth root, and enhance mechanical strength through a good implant design. Therefore, putting great emphasis on implant design will elevate the successful rate of surgery. This thesis mainly studies the implant-bone mechanical behavior, including the insertion torque, the implant-bone interfaces stability, and stress distribution of marginal bone. The research methods include biomechanical test, finite element analysis, and mathematic model analysis. The experimental results will be the basic information of the numerical methods and compare with the standing numerical methods. In the insertion torque study, flute shape plays a significant role in decreasing the torque of initial insertion and being good for initial insertion. The conical implant has the tighter bony contact at the tail thread. In addition, the conical implant with bowl flutes is the optimal design with the highest stability. In the implant-stability analysis study, the assumed displacement should be within the final pullout regions. In addition, the stress index is the last correlated to the holding power. On the other hand, the reaction force within the final regions is better to be highly correlative with the holding power of the implant than the stress index. For the mathematic model study, the calculated values are quite well to correlate with the difference trend of pullout strength, especially for the cylindrical implants. The thread shape and profile should be formulated by modifying the slippage mechanism at the implant-bone interfaces and simulating the strength change in the squeezed bones. For the stress distribution of marginal bone study, the greatest stress in the surrounding bone was consistently concentrated at the root radii of the first thread. Compare with the other threads, the square thread with a 0.60-mm pitch possessed the optimal contact area and stress values.