Analysis of the stress state in articular cartilage defect repairing area_Journal of Biomedical Engineering

Authors：

 LIU Haiying ^1,2 , ZHAO Yongzheng ^1,2 , ZHAO Sen ^1,2 , FENG Jingjing ^1,2,3 , ZHANG Chunqiu ^1,2

1. Tianjin Key Laboratory for Advanced Mechatronic System Design and Intelligent Control, Tianjin 300384, P.R.China;
2. National Demonstration Center for Experimental Mechanical and Electrical Engineering Education, Tianjin University of Technology, Tianjin 300384, P.R.China;
3. Beijing University of Technology, College of Mechanical Engineering, Beijing 100124, P.R.China;

Corresponding author：

LIU Haiying, Email: liuhaiying22@163.com

Keywords：

transversely isotropic; defect repair; stress state; deformation type

DOI：

10.7507/1001-5515.201712083

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Based on transversely isotropic theory, a finite element model for three-dimensional solid-liquid coupling defect repair of articular cartilage was established. By studying stress state of host cartilage near the restoration interface, we identified deformation type of cartilage and discussed the cause of restoration interface cracking. The results showed that the host cartilage surface node near the restoration interface underwent compression deformation in the condition of surface layer defect repair. When the middle layer, deep layer or full-thickness defect were repaired, the node underwent tensile deformation. At this point, the radial dimension of cartilage increased, which might cause restoration interface cracking. If elastic modulus of the tissue engineered cartilage (TEC) was lower (0.1 MPa, 0.3 MPa), the host cartilage surface layer and middle layer mainly underwent tensile deformation. While elastic modulus of TEC was higher (0.6 MPa, 0.9 MPa), each layer of host cartilage underwent compression deformation. Therefore, the elastic modulus of TEC could be increased properly for full-thickness defect repair. This article provides a new idea for evaluating the effect of cartilage tissue engineering repair, and has a certain guiding significance for clinical practice.

Citation： LIU Haiying, ZHAO Yongzheng, ZHAO Sen, FENG Jingjing, ZHANG Chunqiu. Analysis of the stress state in articular cartilage defect repairing area. Journal of Biomedical Engineering, 2018, 35(5): 705-712, 719. doi: 10.7507/1001-5515.201712083 Copy

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13.	何祝斌, 苑世剑, 王仲仁. 应力分量变化范围的描述方程及其图形. 力学季刊, 2006, 27(3): 528-534.
14.	王仲仁, 何祝斌. 一点的正应力三维图形. 塑性工程学报, 2003, 10(1): 4-8.
15.	王仲仁, 戴昆. 一点的三维剪应力图及其与金属变形类型的对应关系. 金属学报, 2000, 36(1): 46-50.
16.	何祝斌, 王仲仁, 苑世剑. 作用于一点的正应力和剪应力三维图形及其在金属成形分析中的应用. 金属学报, 2004, 40(3): 319-325.
17.	徐敬, 赵建宁, 徐海栋, 等. 关节软骨损伤修复研究进展. 临床与病理杂志, 2015, 35(3): 455-461.
18.	Warner M D, Taylor W R, Clift S E. Cyclic loading moves the peak stress to the cartilage surface in a biphasic model with isotropic solid phase properties. Med Eng Phys, 2004, 26(3): 247-249.
19.	张学亮, 刘舒云, 郭维民, 等. 骨软骨一体化仿生支架的研究现状与展望. 中国医药生物技术, 2017, 12(4): 350-355.
20.	Li L P, Buschmann M D, Shirazi-Adl A. A fibril reinforced nonhomogeneous poroelastic model for articular cartilage: inhomogeneous response in unconfined compression. Journal of Biomechanics, 2000, 33(12): 1533-1541.
21.	Jazrawi L M, Alaia M J, Chang G, et al. Advances in magnetic resonance imaging of articular cartilage. Journal of the American Academy of Orthopaedic Surgeons, 2011, 19(7): 420-429.
22.	翟文杰, 翟中勇. 软骨组织无约束压缩的有限元分析. 医用生物力学, 2012, 27(6): 630-635.
23.	卫小春. 关节软骨. 北京: 科学出版社, 2007: 1-302.

1. Sartori-Cintra A R, Aikawa P, Cintra D E. Obesity versus osteoarthritis: beyond the mechanical overload. Einstein, 2014, 12(3): 374-379.
2. Vannini F, Spalding T, Andriolo L, et al. Sport and early osteoarthritis: the role of sport in aetiology, progression and treatment of knee osteoarthritis. Knee Surg Sports Traumatol Arthrosc, 2016, 24(6): 1786-1796.
3. Brody L T. Knee osteoarthritis: Clinical connections to articular cartilage structure and function. Phys Ther Sport, 2015, 16(4): 301-316.
4. 潘育松, 丁国新, 王静. 组织工程软骨修复关节软骨损伤和缺损. 生物医学工程学杂志, 2013, 30(2): 432-437.
5. Akman Y E, Sukur E, Senel A, et al. The comparison of the effects of a novel hydrogel compound and traditional hyaluronate following micro-fracture procedure in a rat full-thickness chondral defect model. Acta Orthop Traumatol Turc, 2017, 51(4): 331-336.
6. Braman J P, Bruckner J D, Clark J M, et al. Articular cartilage adjacent to experimental defects is subject to atypical strains. Clin Orthop Relat Res, 2005, 430: 202-207.
7. Strauss E J, Goodrich L R, Chen C T, et al. Biochemical and biomechanical properties of lesion and adjacent articular cartilage after chondral defect repair in an equine model. American Journal of Sports Medicine, 2005, 33(11): 1647-1653.
8. 孟迪, 张春秋, 刘海英, 等. 软骨缺损形状对组织工程修复区的力学影响. 生物医学工程与临床, 2016, 20(1): 9-14.
9. Clark J M. The organisation of collagen fibrils in the superficial zones of articular cartilage. Journal of Anatomy,, 1990, 171: 117-130.
10. Donzelli P S, Spilker R L. A finite element investigation of solid phase transverse isotropy in contacting biphasic cartilage layers. Advances in Bioengineering, 1996, 33:349-350.
11. Elhamian S M, Alizadeh M, Shokrieh M M, et al. A depth dependent transversely isotropic micromechanic model of articular cartilage. Journal of Materials Science Materials in Medicine, 2015, 26(2): 111-121.
12. 邵越峰, 卫小春. 应力状态下软骨基质分解代谢的变化. 中国骨伤, 2009, 22(3): 241-244.
13. 何祝斌, 苑世剑, 王仲仁. 应力分量变化范围的描述方程及其图形. 力学季刊, 2006, 27(3): 528-534.
14. 王仲仁, 何祝斌. 一点的正应力三维图形. 塑性工程学报, 2003, 10(1): 4-8.
15. 王仲仁, 戴昆. 一点的三维剪应力图及其与金属变形类型的对应关系. 金属学报, 2000, 36(1): 46-50.
16. 何祝斌, 王仲仁, 苑世剑. 作用于一点的正应力和剪应力三维图形及其在金属成形分析中的应用. 金属学报, 2004, 40(3): 319-325.
17. 徐敬, 赵建宁, 徐海栋, 等. 关节软骨损伤修复研究进展. 临床与病理杂志, 2015, 35(3): 455-461.
18. Warner M D, Taylor W R, Clift S E. Cyclic loading moves the peak stress to the cartilage surface in a biphasic model with isotropic solid phase properties. Med Eng Phys, 2004, 26(3): 247-249.
19. 张学亮, 刘舒云, 郭维民, 等. 骨软骨一体化仿生支架的研究现状与展望. 中国医药生物技术, 2017, 12(4): 350-355.
20. Li L P, Buschmann M D, Shirazi-Adl A. A fibril reinforced nonhomogeneous poroelastic model for articular cartilage: inhomogeneous response in unconfined compression. Journal of Biomechanics, 2000, 33(12): 1533-1541.
21. Jazrawi L M, Alaia M J, Chang G, et al. Advances in magnetic resonance imaging of articular cartilage. Journal of the American Academy of Orthopaedic Surgeons, 2011, 19(7): 420-429.
22. 翟文杰, 翟中勇. 软骨组织无约束压缩的有限元分析. 医用生物力学, 2012, 27(6): 630-635.
23. 卫小春. 关节软骨. 北京: 科学出版社, 2007: 1-302.

Journal of Biomedical Engineering

Analysis of the stress state in articular cartilage defect repairing area

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