Effects of removing superficial layer of cartilage on the surface morphology and mechanical behavior of cartilage_Journal of Biomedical Engineering

Authors：

WANG Yabo ^1,2 ,  LIU Jie ^1,2 ,  GAO Lilan ^1,2,3,4 , TAN Yansong ^1,2 , CHEN Ruiqi ^1,2 , ZHANG Chunqiu ^1,2,3,4

1. Tianjin Key Laboratory for Advanced Mechatronic System Design and Intelligent Control, School of Mechanical Engineering, Tianjin University of Technology, 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. Tianjin Key Laboratory of Bone Implant Interface Functionalization and Personality, Tianjin 300190, P. R. China;
4. Just Medical Devices (Tianjin) Co., LTD, Tianjin 300190, P. R. China;

Corresponding author：

LIU Jie, Email: liujiejane@163.com; GAO Lilan, Email: gaolilan780921@163.com

Keywords：

Articular cartilage; Superficial injury of cartilage; Surface topography; Mechanical properties

DOI：

10.7507/1001-5515.202308032

Video：

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Superficial cartilage defect is an important factor that causes osteoarthritis. Therefore, it is very important to investigate the influence of superficial cartilage defects on its surface morphology and mechanical properties. In this study, the knee joint cartilage samples of adult pig were prepared, which were treated by enzymolysis with chymotrypsin and physical removal with electric friction pen, respectively. Normal cartilage and surface treated cartilage were divided into five groups: control group (normal cartilage group), chymotrypsin immersion group, chymotrypsin wiping group, removal 10% group with electric friction pen, and removal 20% group with electric friction pen. The surface morphology and structure of five groups of samples were characterized by laser spectrum confocal microscopy and environmental field scanning electron microscopy, and the mechanical properties of each group of samples were evaluated by tensile tests. The results show that the surface arithmetic mean height and fracture strength of the control group were the smallest, and the fracture strain was the largest. The surface arithmetic mean height and fracture strength of the removal 20% group with electric friction pen were the largest, and the fracture strain was the smallest. The surface arithmetic mean height, fracture strength and fracture strain values of the other three groups were all between the above two groups, but the surface arithmetic mean height and fracture strength of the removal 10% group with electric friction pen, the chymotrypsin wiping group and the chymotrypsin soaking group decreased successively, and the fracture strain increased successively. In addition, we carried out a study on the elastic modulus of different groups, and the results showed that the elastic modulus of the control group was the smallest, and the elastic modulus of the removal 20% group with electric friction pen was the largest. The above study revealed that the defect of the superficial area of cartilage changed its surface morphology and structure, and reduced its mechanical properties. The research results are of great significance for the prevention and repair of cartilage injury.

Citation： WANG Yabo, LIU Jie, GAO Lilan, TAN Yansong, CHEN Ruiqi, ZHANG Chunqiu. Effects of removing superficial layer of cartilage on the surface morphology and mechanical behavior of cartilage. Journal of Biomedical Engineering, 2024, 41(2): 328-334. doi: 10.7507/1001-5515.202308032 Copy

1.	Kumar P, Oka M, Toguchida J, et al. Role of uppermost superficial surface layer of articular cartilage in the lubrication mechanism of joints. Journal of Anatomy, 2001, 199(3): 241-250.
2.	Hunziker E B, Michel M, Studer D. Ultrastructure of adult human articular cartilage matrix after cryotechnical processing. Microscopy Research and Technique, 1997, 37(4): 271-284.
3.	Fujioka R, Aoyama T, Takakuwa T. The layered structure of the articular surface. Osteoarthritis and Cartilage, 2013, 21(8): 1092-1098.
4.	Chiang E H, Laing T J, Meyer C R, et al. Ultrasonic characterization of in vitro osteoarthritic articular cartilage with validation by confocal microscopy. Ultrasound in Medicine and Biology, 1997, 23(2): 205-213.
5.	Li G,Yin J, Gao J, et al. Subchondral bone in osteoarthritis: insight into risk factors and microstructural changes. Arthritis Research and Therapy, 2013, 15(6): 223.
6.	黄凌岸, 李鹏翠, 卫小春, 等. 关节软骨生物力学建模理论与试验方法研究进展. 中国骨与关节损伤杂志, 2020, 35(1): 107-109.
7.	陈崇伟, 卫小春. 关节软骨浅表层的透射电镜观察. 山西医科大学学报, 2005, 36(1): 44-46.
8.	Jurvelin J S, Müller D J, Wong M, et al. Surface and subsurface morphology of bovine humeral articular cartilage as assessed by atomic force and transmission electron microscopy. Journal of Structural Biology, 1996, 17(1): 45-54.
9.	Stanescu R. Effects of enzymatic digestions on the negative charge of articular cartilage surface. The Journal of Rheumatology, 1985, 2(5): 833-840.
10.	Neu C P, Hull M L, Walton J H. Heterogeneous threedimensional strain fields during unconfined cyclic compression in bovine articular cartilage explants. Journal of Orthopaedic Research, 2005, 23(6): 1390-1398.
11.	Kempson G E. Age-related changes in the tensile properties of human articular cartilage: a comparative study between the femoral head of the hip joint and the talus of the ankle joint. Biochimica et Biophysica Acta (BBA)-General Subjects, 1991, 1075(3): 223-230.
12.	Schmidt M B, Mow V C, Chun L E, et al. Effects of proteoglycan extraction on the tensile behavior of articular cartilage. Journal of Orthopaedic Research, 1990, 8(3): 353-363.
13.	Poole A R, Pidoux I, Reiner A, et al. An immunoelectron microscope study of the organization of proteoglycan monomer, link protein, and collagen in the matrix of articularcartilage. Journal of Cell Biology, 1982, 93(3): 921-937.
14.	Torzilli P A. Mechanical response of articular cartilage to an oscillating load. Mechanics Research Communications, 1984, 11(1): 75-82.
15.	Kempson G E. Relationship between the tensile properties of articular cartilage from the human knee and age. Annals of the Rheumatic Diseases, 1982, 41(5): 508-511.
16.	Guilak F, Ratcliffe A, Lane N, et al. Mechanical and biochemical changes in the superficial zone of articular cartilage in canine experimental osteoarthritis. Journal of Orthopaedic Research, 1994, 12(4): 474-484.
17.	Mow V C, Ratcliffe A, Poole A R. Cartilage and diarthrodial joints as paradigms for hierarchical materials and structures. Biomaterials, 1991, 13(2): 67-97.
18.	Wong M, Hunziker E B. Articular cartilage biology and mechanics. Sports Medicine and Arthroscopy Review, 1998, 6(1): 4-12.
19.	Woo S L, Akeson W H, Jemmott G F. Measurements of nonhomodeneous directional mechanical properties of articular cartilage in tension. Journal of Biomechanics, 1976, 9(12): 785-791.
20.	Kempson G E, Freeman M A, Swanson S A. Tensile properties of articular cartilage. Nature, 1968, 220(5172): 1127-1128.
21.	Woo S L, Lubock P, Gomez M A, et al. Large deformation nonhomogeneous and directional properties of articular cartilage in uniaxial tension. Journal of Biomechanics, 1979, 12(6): 437-446.
22.	Huang C Y, Stankiewicz A, Ateshian G A, et al. Anisotropy, inhomogeneity, and tension-compression nonlinearity of human glenohumeral cartilage in finite deformation. Journal of Biomechanics, 2005, 38(4): 799-809.
23.	Gao Lilan, Zhang Chunqiu, Gao Hong, et al. Depth and rate dependent mechanical behaviors for articular cartilage: Experiments and theoretical predictions. Materials Science and Engineering C, 2014, 38: 244-251.
24.	Akizuki S, Mow V C, Müller F, et al. Tensile properties of human knee joint cartilage: I. influence of ionic conditions, weight bearing and fibrillation on the tensile modulus. Journal of Orthopaedic Research, 1986, 4(4): 379-392.
25.	Roth V, Mow V C. The intrinsic tensile behavior of the matrix of bovine articular cartilage and its variation with age. The Journal of Bone and Joint Surgery, 1980, 62(7): 1102-1117.
26.	Mow V C, Guo X E. Mechano-electrochemical properties of articular cartilage: their inhomogeneities and anisotropies. Annual Review of Biomedical Engineering, 2002, 4: 175-209.
27.	司雲朋, 高丽兰, 张春秋, 等. 含裂纹缺损关节软骨的单轴准静态拉伸性能. 中国组织工程研究, 2020, 24(2): 187-191.
28.	曹红, 李婷婷, 邹军, 等. 关节软骨力学特征研究进展. 医用生物力学, 2020, 35(4): 383-388.
29.	程杰平, 马洪顺, 褚怀德. 骨性关节炎对膝关节软骨力学性质影响的实验研究. 医用生物力学, 2005, 20(1): 25-27.
30.	龚虎臣, 门玉涛, 赵忠海, 等. 胶原纤维束对软骨力学性能的影响. 医用生物力学, 2020, 35(6): 705-711.

1. Kumar P, Oka M, Toguchida J, et al. Role of uppermost superficial surface layer of articular cartilage in the lubrication mechanism of joints. Journal of Anatomy, 2001, 199(3): 241-250.
2. Hunziker E B, Michel M, Studer D. Ultrastructure of adult human articular cartilage matrix after cryotechnical processing. Microscopy Research and Technique, 1997, 37(4): 271-284.
3. Fujioka R, Aoyama T, Takakuwa T. The layered structure of the articular surface. Osteoarthritis and Cartilage, 2013, 21(8): 1092-1098.
4. Chiang E H, Laing T J, Meyer C R, et al. Ultrasonic characterization of in vitro osteoarthritic articular cartilage with validation by confocal microscopy. Ultrasound in Medicine and Biology, 1997, 23(2): 205-213.
5. Li G,Yin J, Gao J, et al. Subchondral bone in osteoarthritis: insight into risk factors and microstructural changes. Arthritis Research and Therapy, 2013, 15(6): 223.
6. 黄凌岸, 李鹏翠, 卫小春, 等. 关节软骨生物力学建模理论与试验方法研究进展. 中国骨与关节损伤杂志, 2020, 35(1): 107-109.
7. 陈崇伟, 卫小春. 关节软骨浅表层的透射电镜观察. 山西医科大学学报, 2005, 36(1): 44-46.
8. Jurvelin J S, Müller D J, Wong M, et al. Surface and subsurface morphology of bovine humeral articular cartilage as assessed by atomic force and transmission electron microscopy. Journal of Structural Biology, 1996, 17(1): 45-54.
9. Stanescu R. Effects of enzymatic digestions on the negative charge of articular cartilage surface. The Journal of Rheumatology, 1985, 2(5): 833-840.
10. Neu C P, Hull M L, Walton J H. Heterogeneous threedimensional strain fields during unconfined cyclic compression in bovine articular cartilage explants. Journal of Orthopaedic Research, 2005, 23(6): 1390-1398.
11. Kempson G E. Age-related changes in the tensile properties of human articular cartilage: a comparative study between the femoral head of the hip joint and the talus of the ankle joint. Biochimica et Biophysica Acta (BBA)-General Subjects, 1991, 1075(3): 223-230.
12. Schmidt M B, Mow V C, Chun L E, et al. Effects of proteoglycan extraction on the tensile behavior of articular cartilage. Journal of Orthopaedic Research, 1990, 8(3): 353-363.
13. Poole A R, Pidoux I, Reiner A, et al. An immunoelectron microscope study of the organization of proteoglycan monomer, link protein, and collagen in the matrix of articularcartilage. Journal of Cell Biology, 1982, 93(3): 921-937.
14. Torzilli P A. Mechanical response of articular cartilage to an oscillating load. Mechanics Research Communications, 1984, 11(1): 75-82.
15. Kempson G E. Relationship between the tensile properties of articular cartilage from the human knee and age. Annals of the Rheumatic Diseases, 1982, 41(5): 508-511.
16. Guilak F, Ratcliffe A, Lane N, et al. Mechanical and biochemical changes in the superficial zone of articular cartilage in canine experimental osteoarthritis. Journal of Orthopaedic Research, 1994, 12(4): 474-484.
17. Mow V C, Ratcliffe A, Poole A R. Cartilage and diarthrodial joints as paradigms for hierarchical materials and structures. Biomaterials, 1991, 13(2): 67-97.
18. Wong M, Hunziker E B. Articular cartilage biology and mechanics. Sports Medicine and Arthroscopy Review, 1998, 6(1): 4-12.
19. Woo S L, Akeson W H, Jemmott G F. Measurements of nonhomodeneous directional mechanical properties of articular cartilage in tension. Journal of Biomechanics, 1976, 9(12): 785-791.
20. Kempson G E, Freeman M A, Swanson S A. Tensile properties of articular cartilage. Nature, 1968, 220(5172): 1127-1128.
21. Woo S L, Lubock P, Gomez M A, et al. Large deformation nonhomogeneous and directional properties of articular cartilage in uniaxial tension. Journal of Biomechanics, 1979, 12(6): 437-446.
22. Huang C Y, Stankiewicz A, Ateshian G A, et al. Anisotropy, inhomogeneity, and tension-compression nonlinearity of human glenohumeral cartilage in finite deformation. Journal of Biomechanics, 2005, 38(4): 799-809.
23. Gao Lilan, Zhang Chunqiu, Gao Hong, et al. Depth and rate dependent mechanical behaviors for articular cartilage: Experiments and theoretical predictions. Materials Science and Engineering C, 2014, 38: 244-251.
24. Akizuki S, Mow V C, Müller F, et al. Tensile properties of human knee joint cartilage: I. influence of ionic conditions, weight bearing and fibrillation on the tensile modulus. Journal of Orthopaedic Research, 1986, 4(4): 379-392.
25. Roth V, Mow V C. The intrinsic tensile behavior of the matrix of bovine articular cartilage and its variation with age. The Journal of Bone and Joint Surgery, 1980, 62(7): 1102-1117.
26. Mow V C, Guo X E. Mechano-electrochemical properties of articular cartilage: their inhomogeneities and anisotropies. Annual Review of Biomedical Engineering, 2002, 4: 175-209.
27. 司雲朋, 高丽兰, 张春秋, 等. 含裂纹缺损关节软骨的单轴准静态拉伸性能. 中国组织工程研究, 2020, 24(2): 187-191.
28. 曹红, 李婷婷, 邹军, 等. 关节软骨力学特征研究进展. 医用生物力学, 2020, 35(4): 383-388.
29. 程杰平, 马洪顺, 褚怀德. 骨性关节炎对膝关节软骨力学性质影响的实验研究. 医用生物力学, 2005, 20(1): 25-27.
30. 龚虎臣, 门玉涛, 赵忠海, 等. 胶原纤维束对软骨力学性能的影响. 医用生物力学, 2020, 35(6): 705-711.

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