Design the femoral implant matched anatomical Ti64 implant and compare among lattice structures topology optimization and cylindrical pores

Abstract

Trabecular bone, a porous and spongy kind of bone tissue composed of a lattice of connecting rods and/or plates, is crucial for the transfer of weight in crucial joints including the spine, hip, and knee. It is impacted by a variety of metabolic bone illnesses, such as osteoporosis, which result in bone loss, reduced bone strength, and an elevated risk of bone fracture. To promote osseointegration due to the permeable porous, we suggest, in this study, a new approach to design a femoral permeable porous implant to achieve suitable stiffness, lightweight, and biocompatibility for the bone. Accordingly, data are collected from a digital bio-model to design a femoral implant for mimics segmental bone defect (SBD) with a biocompatible material Ti6Al4V (Ti64). To do this, three lattice structures (LSs) are compared and derived from implicit surface modeling called a triply periodic minimal surface (TPMS) to obtain the LS suitable to create it within the solid inner volume of the tibia implant. Thus, performed the finite element analysis (FEA) method for the enhanced Designs and compare them in terms of stress, deformation, and lightweight.