Biomechanical analysis and design of a dynamic spinal fixator using topology optimization: a finite element analysis

被引:18
|
作者
Lin, Hung-Ming [1 ]
Liu, Chien-Lin [2 ]
Pan, Yung-Ning [1 ]
Huang, Chang-Hung [3 ]
Shih, Shih-Liang [4 ]
Wei, Shun-Hwa [5 ]
Chen, Chen-Sheng [5 ]
机构
[1] Natl Taiwan Univ, Dept Mech Engn, Taipei 10764, Taiwan
[2] Taipei Vet Gen Hosp, Dept Orthoped Surg, Taipei, Taiwan
[3] Mackay Mem Hosp, Dept Med Res, New Taipei City, Taiwan
[4] Taipei City Hosp, Dept Orthopaed Surg, Zhong Xing Branch, Taipei, Taiwan
[5] Natl Yang Ming Univ, Dept Phys Therapy & Assist Technol, Taipei 112, Taiwan
来源
MEDICAL & BIOLOGICAL ENGINEERING & COMPUTING | 2014年 / 52卷 / 05期
关键词
Finite element analysis; Biomechanics; Dynamic spinal stabilization devices; Dynesys; Topology optimization; LUMBAR SPINE; STABILIZATION SYSTEM; IN-VITRO; ADJACENT; DISC; FUSION; ARTHROPLASTY; SEGMENT; NEUTRALIZATION; DEGENERATION;
D O I
10.1007/s11517-014-1154-x
中图分类号
TP39 [计算机的应用];
学科分类号
081203 ; 0835 ;
摘要
Surgeons often use spinal fixators to manage spinal instability. Dynesys (DY) is a type of dynamic fixator that is designed to restore spinal stability and to provide flexibility. The aim of this study was to design a new spinal fixator using topology optimization [the topology design (TD) system]. Here, we constructed finite element (FE) models of degenerative disc disease, DY, and the TD system. A hybrid-controlled analysis was applied to each of the three FE models. The rod structure of the topology optimization was modelled at a 39 % reduced volume compared with the rigid rod. The TD system was similar to the DY system in terms of stiffness. In contrast, the TD system reduced the cranial adjacent disc stress and facet contact force at the adjacent level. The TD system also reduced pedicle screw stresses in flexion, extension, and lateral bending.
引用
收藏
页码:499 / 508
页数:10
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