Dynamic Analysis of Hip Prosthesis Using Different Biocompatible Alloys

Abstract

Abstract In the present paper, a three-dimensional finite element model of the Charnley implant has been developed to analyze the stress–strain distribution and deformation over the stem prosthesis. Patient-specific dynamic forces have been considered for the analytical evaluation using commercial finite element code. The impact of each dynamic activity has been analyzed separately using six different biocompatible alloy materials made of titanium and cobalt-chromium. Mechanical parameters have been evaluated to envisage the longevity and functionality of the implant. The performance of different materials for each suitable gait pattern is analyzed using finite element code. Consequently, Cobalt chromium alloys (CoCrMo alloy) demonstrate better results, i.e., maximum stress, minimum deformation, and strain as compared with other materials. Every dynamic motion, viz., walking, standing up, sitting down, going upstairs, and going downstairs are found in good agreement with the safety factor for every biomaterial. Additionally, going downstairs and sitting down gait motion exhibits the maximum and minimum stress–strain level, respectively. Based on the outcome of the presurgical study, it is recommended that CoCrMo alloys should be preferred over other materials.