Structural design and evaluation of bone remodeling effect of fracture internal fixation implants with time-varying stiffness_Journal of Biomedical Engineering

Authors：

SUN Hao ¹ ,  DING Xiaohong ¹ , XU Shipeng ² , DUAN Pengyun ¹ , XIONG Min ¹ , ZHANG Heng ¹

1. School of Mechanical Engineering, University of Shanghai for Science and Technology, Shanghai 200093, P. R. China;
2. Shanghai Special Equipment Supervision and Inspection Technology Research Institute, Shanghai 200062, P. R. China;

Corresponding author：

DING Xiaohong, Email: dingxh@usst.edu.cn

Keywords：

Topology optimization; Time-varying stiffness; Composite structure; Biodegradation; Bone remodeling

DOI：

10.7507/1001-5515.202311037

Video：

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Abstract Full text Figures/Tables Video References Cited by

The stiffness of an ideal fracture internal fixation implant should have a time-varying performance, so that the fracture can generate reasonable mechanical stimulation at different healing stages, and biodegradable materials meet this performance. A topology optimization design method for composite structures of fracture internal fixation implants with time-varying stiffness is proposed, considering the time-dependent degradation process of materials. Using relative density and degradation residual rate to describe the distribution and degradation state of two materials with different degradation rates and elastic modulus, a coupled mathematical model of degradation simulation mechanical analysis was established. Biomaterial composite structures were designed based on variable density method to exhibit time-varying stiffness characteristics. Taking the bone plate used for the treatment of tibial fractures as an example, a composite structure bone plate with time-varying stiffness characteristics was designed using the proposed method. The optimization results showed that material 1 with high stiffness formed a columnar support structure, while material 2 with low stiffness was distributed at the degradation boundary and inside. Using a bone remodeling simulation model, the optimized bone plates were evaluated. After 11 months of remodeling, the average elastic modulus of callus using degradable time-varying stiffness plates, titanium alloy plates, and stainless steel plates were 8 634 MPa, 8 521 MPa, and 8 412 MPa, respectively, indicating that the use of degradable time-varying stiffness plates would result in better remodeling effects on the callus.

Citation： SUN Hao, DING Xiaohong, XU Shipeng, DUAN Pengyun, XIONG Min, ZHANG Heng. Structural design and evaluation of bone remodeling effect of fracture internal fixation implants with time-varying stiffness. Journal of Biomedical Engineering, 2024, 41(3): 595-603. doi: 10.7507/1001-5515.202311037 Copy

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1. Agarwal S, Curtin J, Duffy B, et al. Biodegradable magnesium alloys for orthopaedic applications: A review on corrosion, biocompatibility and surface modifications. Mater Sci Eng C, 2016, 68(1): 948-963.
2. Markert Z B. Numerical simulation of the tissue differentiation and corrosion process of biodegradable magnesium implants during bone fracture healing. Zamm-Z Angew Math Me, 2018, 98(12): 2223-2238.
3. Zberg B, Uggowitzer P J, Löffler J F. MgZnCa glasses without clinically observable hydrogen evolution for biodegradable implants. Nat Mater, 2009, 8(11): 887-891.
4. Zheng Y F, Gu X N, Witte F. Biodegradable metals. Mat Sci Eng R, 2014, 77: 1-34.
5. Wang J, Xu J, Hopkins C, et al. Biodegradable magnesium-based implants in orthopedics-A general review and perspectives. Adv Sci, 2020, 7(8): 1902443.
6. Parande G, Manakari V, Gupta H, et al. Magnesium-β-tricalcium phosphate composites as a potential orthopedic implant: A mechanical/damping/immersion perspective. Metals, 2018, 8(5): 343.
7. Dutta S, Gupta S, Roy M. Recent developments in magnesium metal-matrix composites for biomedical applications: A review. Acs Biomater Sci Eng, 2020, 6(9): 4748-4773.
8. Wu C, Zheng K, Fang J G, et al. Time-dependent topology optimization of bone plates considering bone remodeling. Comput Method Appl M, 2020, 359: 112702.
9. Chandra G, Pandey A, Pandey S. Design of a biodegradable plate for femoral shaft fracture fixation. Med Eng Phys, 2020, 81: 86-96.
10. Li C, Wu C, Lin C. Design of a patient-specific mandible reconstruction implant with dental prosthesis for metal 3D printing using integrated weighted topology optimization and finite element analysis. J Mech Behav Biomed, 2020, 105: 103700.
11. Arabnejad K S, Pasini D. Multiscale design and multiobjective optimization of orthopedic hip implants with functionally graded cellular material. J Biomech Eng-T Asme, 2012, 134(3): 031004.
12. Kirkland N T, Birbilis N, Staiger M P. Assessing the corrosion of biodegradable magnesium implants: a critical review of current methodologies and their limitations. Acta Biomater, 2012, 8: 925-936.
13. Keerthiga G, Prasad M J N V, Vijayshankar D, et al. Polymeric coatings for magnesium alloys for biodegradable implant application: A review. Materials, 2023, 16: 4700.
14. Knigge S, Mueller M, Fricke L, et al. In vitro investigation of corrosion control of magnesium with degradable polycaprolactone coatings for cardiovascular grafts. Coating, 2023, 12(1): 94.
15. Grogan J A, Brien O, Leen S B, et al. A corrosion model for bioabsorbable metallic stents. Acta Biomater, 2011, 7(9): 3523-3533.
16. Yun K S, Youn S K. Topology optimization of viscoelastic damping layers for attenuating transient response of shell structures. Finite Elem Anal Des, 2018, 141: 154-165.
17. 徐世鹏. 基于骨愈合理论的骨折内固定植入物优化设计方法研究. 上海: 上海理工大学, 2023.
18. Gu X, Kang J, Zhu J. 3D cellular automata-based numerical simulation of atmospheric corrosion process on weathering steel. J Mater Civil Eng, 2018, 30(11): 04018296.
19. Wang C F, Qian X P. Heaviside projection-based aggregation in stress-constrained topology optimization. Int J Numer Meth Eng, 2018, 115(7): 849-871.
20. Zhang H, Ding X H, Li H, et al. Multi-scale structural topology optimization of free-layer damping structures with damping composite materials. Compos Struct, 2019, 212: 609-624.
21. Zheng K, Yoda N, Chen J, et al. Bone remodeling following mandibular reconstruction using fibula free flap. J Biomech, 2022, 133: 110968.
22. Cheong V S, Blunn G W, Coathup M J, et al. A novel adaptive algorithm for 3D finite element analysis to model extracortical bone growth. Comput Method Biomec, 2018, 21(2): 129-138.

Journal of Biomedical Engineering

Structural design and evaluation of bone remodeling effect of fracture internal fixation implants with time-varying stiffness

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