Topology Optimization of Bionic Porous Structure Based on Biomechanical Properties of Trabecular Bone
10.16156/j.1004-7220.2018.05.04
- VernacularTitle:仿骨小梁力学性能的多孔结构拓扑优化设计
- Author:
Xinlu GUO
1
;
Rong LIU
1
;
Yongxuan WANG
2
Author Information
1. School of Biomedical Engineering, Dalian University of Technology
2. Orthopedic Laboratory, Affiliated Zhongshan Hospital of Dalian University
- Publication Type:Journal Article
- Keywords:
trabecular bone;
porous structure;
representative-volume-element (RVE) method;
mechanical analysis;
topology optimization
- From:
Journal of Medical Biomechanics
2018;33(5):E402-E409
- CountryChina
- Language:Chinese
-
Abstract:
Objective Based on structure of animal trabecular bone, implants with porous structure were designed to describe mechanical properties of trabecular structure and explain significance of bionic trabecular porous implants in clinical treatment. Methods Based on anisotropic mechanical properties of animal trabecular bone, a porous structure was designed using the topology optimization method. The principles of partition and block reconstruction were first proposed according to bone function theory. The trabecular structure was then reconstructed based on micro-CT images. The boundary constraint and external load were applied on this model according to the respective-volume-element (RVE) method. Taking the solved mechanical properties as objective functions of optimization, the porous structure design and optimization were conducted using the variable density method and the homogenization method. Results The trabecular bone possessed the anisotropic mechanical properties. It was found that the volume fraction showed an increasing trend from the edge to the middle across the same section of trabecular bone. But there was no obvious regular pattern in Poisson’s ratio, which was evenly distributed in the range between 0.17 and 0.30. As to the values of elastic modulus and shear modulus, they were both significantly higher in the main pressure position compared with those in the other positions. After topography optimization based on these mechanical properties, the Poisson’s ratio of the optimized model was in the same range as the animal trabecular bone. The elastic modulus error was less than 14%, with the minimum being only 3%. In addition, the shear modulus error was below 8%, which ultimately complied with criteria of the original goal. Conclusions The designed porous structure based on topology optimization had the same anisotropic characteristics as animal trabecular bone, while reducing the stress concentration phenomenon, which could achieve the specific design for porous structure, thus providing a reasonable and effective method for clinical porous implants.
