Study on the effect of artificial cartilage with different elastic modulus on the mechanical environment of the chondrocyte in defect cartilage repaired area_Journal of Biomedical Engineering

Authors：

DUAN Hangtian ¹ ,  LIU Haiying ¹ , WANG Wei ² , ZHANG Chunqiu ¹ , SONG Shubo ³ , HUANG Yunpeng ⁴

1. Tianjin Key Laboratory of the Design and Intelligent Control of the Advanced Mechatronical System, Tianjin University of Technology, Tianjin 300384, P.R.China;
2. Department of Mechanics, School of Mechanical Engineering, Tianjin University, Tianjin 300354, P.R.China;
3. China Automobile Industry Engineering Co.,Ltd, Tianjin 300113, P.R.China;
4. Department of Orthopaedics, First Affiliated Hospital of Fujian Medical University, Fuzhou 350005, P.R.China;

Corresponding author：

LIU Haiying, Email: liuhaiying22@163.com

Keywords：

numerical simulation; cartilage defect; chondrocyte; stress; flow field

DOI：

10.7507/1001-5515.201605002

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Abstract Full text Figures/Tables Video References Cited by

A solid-liquid two-phase finite element model of articular cartilage and a microscopic finite element model of chondrocytes were established using the finite element software COMSOL in this study. The purpose of the study is to investigate the mechanics environment and the liquid flow field of the host cartilage chondrocytes in each layer by multi-scale method, under physiological load, with the different elastic modulus of artificial cartilage to repair cartilage defect. The simulation results showed that the uniform elastic modulus of artificial cartilage had different influences on the microenvironment of different layer chondrocytes. With the increase of the elastic modulus of artificial cartilage, the stress of the shallow surface layer and the intermediate layer chondrocytes increased and the stress of deep layer chondrocytes decreased. The flow field direction of the middle layer and the bottom layer of cartilage can also be changed by artificial cartilage implantation, as well as the ways of nourishment supply of the middle layer and underlying chondrocytes change. A barrier to underlying chondrocytes nutrition supply may be caused by this, thus resulting in the uncertainty of the repair results. With cross-scale finite element model simulation analysis of chondrocytes, we can quantitatively evaluate the mechanical environment of chondrocytes in each layer of the host cartilage. It is helpful to assess the clinical effect of cartilage defect reparation more accurately.

Citation： DUANHangtian, LIUHaiying, WANGWei, ZHANGChunqiu, SONGShubo, HUANGYunpeng. Study on the effect of artificial cartilage with different elastic modulus on the mechanical environment of the chondrocyte in defect cartilage repaired area. Journal of Biomedical Engineering, 2017, 34(1): 34-40. doi: 10.7507/1001-5515.201605002 Copy

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6.	Mow V C, Lai W, Kuei S, et al. Biphasic creep and stress relaxation of articular cartlage incompression: Theory and experiments. J Biomech Eng, 1980, 102(1): 73-84.
7.	Mak F. Apparent viscoelastic behavior of articular cartilage contributions from intrinsic matrixviscoelasticity and interstitial fluid flow. J Biomech Eng, 1986, 108(2): 123-130.
8.	周海宇, 李元超, 王成焘. 软骨细胞力学环境的跨尺度计算. 医用生物力学, 2012, 27(4): 392-397.
9.	Schinagl M, Gurskis D, Chen C, et al. Depth-dependent confined compression modulus of full-thickness bovine articular cartilage. J Orthop Res, 1997, 15(4): 499-506.
10.	Li L P, Buschmann M D, Shirazi-Adl A. A fibril reinforced nonhomogeneous poroelastic model for articular cartilage: inhomogeneous response in unconfined compression. J Biomech Eng, 2000, 33(12): 1533-1541.
11.	周海宇, 李元超, 王成焘. 关节软骨胶原纤维增强特性. 医用生物力学, 2013, 28(4): 460-465.
12.	Hosoda N, Sakai N, Sawae Y. Finite element analysis of articular cartilage model considering the configuration and biphasic property of the tissue. IFMBE Proc, 2009, 23(7): 1883-1887.
13.	Guilak F. The deformation behavior and viscoelastic properties of chondrocytes in articular cartilage. Biorheology, 2000, 37(1/2): 27-44.
14.	胡雪艳, 恽晓平, 郭忠武, 等. 正常成人步态特征研究. 中国康复理论与实践, 2006, 12(10): 855-857, 封3.
15.	Zignego D L, Jutila A A, Gelbke M K, et al. The mechanical microenvironment of high concentration agarose for applying deformation to primary chondrocytes. J Biomech, 2014, 47(9): 2143-2148.

1. Alexopoulos L G, Setton L A, Guilak F. The biomechanical role of the chondrocyte pericellular matrix in articularcartilabe. Acta Biomater, 2005, 1(3): 317-325.
2. 陈康, 王大平. 组织工程软骨修复关节软骨损伤研究新进展. 中国矫形外科杂志, 2012, 20(8): 721-723.
3. Khoshgoftar M, Ito K, van Donkelaar C C. The influence of cell-matrix attachment and matrix development on the micromechanical environment of the chondrocyte in tissue-engineered cartilage. Tissue Eng Part A, 2014, 20(23/24): 3112-3121.
4. 张述卿, 张春秋, 高丽兰, 等. 组织工程修复关节软骨缺损的力学状态研究. 中国组织工程研究与临床康复, 2011, 15(20): 3629-3632.
5. Muhammad H, Rais Y, Miosge N, et al. The primary cilium as a dual sensor of mechanochemical signals in chondrocytes. Cell Mol Life Sci, 2012, 69(13): 2101-2107.
6. Mow V C, Lai W, Kuei S, et al. Biphasic creep and stress relaxation of articular cartlage incompression: Theory and experiments. J Biomech Eng, 1980, 102(1): 73-84.
7. Mak F. Apparent viscoelastic behavior of articular cartilage contributions from intrinsic matrixviscoelasticity and interstitial fluid flow. J Biomech Eng, 1986, 108(2): 123-130.
8. 周海宇, 李元超, 王成焘. 软骨细胞力学环境的跨尺度计算. 医用生物力学, 2012, 27(4): 392-397.
9. Schinagl M, Gurskis D, Chen C, et al. Depth-dependent confined compression modulus of full-thickness bovine articular cartilage. J Orthop Res, 1997, 15(4): 499-506.
10. Li L P, Buschmann M D, Shirazi-Adl A. A fibril reinforced nonhomogeneous poroelastic model for articular cartilage: inhomogeneous response in unconfined compression. J Biomech Eng, 2000, 33(12): 1533-1541.
11. 周海宇, 李元超, 王成焘. 关节软骨胶原纤维增强特性. 医用生物力学, 2013, 28(4): 460-465.
12. Hosoda N, Sakai N, Sawae Y. Finite element analysis of articular cartilage model considering the configuration and biphasic property of the tissue. IFMBE Proc, 2009, 23(7): 1883-1887.
13. Guilak F. The deformation behavior and viscoelastic properties of chondrocytes in articular cartilage. Biorheology, 2000, 37(1/2): 27-44.
14. 胡雪艳, 恽晓平, 郭忠武, 等. 正常成人步态特征研究. 中国康复理论与实践, 2006, 12(10): 855-857, 封3.
15. Zignego D L, Jutila A A, Gelbke M K, et al. The mechanical microenvironment of high concentration agarose for applying deformation to primary chondrocytes. J Biomech, 2014, 47(9): 2143-2148.

Journal of Biomedical Engineering

Study on the effect of artificial cartilage with different elastic modulus on the mechanical environment of the chondrocyte in defect cartilage repaired area

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