Advances in gradient for osteochondral interface tissue

doi:10.3877/cma.j.issn.1674-134X.2020.06.013

Abstract

Abstract:

Osteochondral tissue is aninterface tissue engineering composed of two distinctly different tissues which are cartilage and bone. These two tissues differ from micro and macro gave the chemical composition, microstructure, mechanical characteristics, bioelectrical characteristics, and physiological metabolism.Given the multiple gradient changes from the articular cartilage surface to the subchondral bone, by fully studying these gradient changes, this review may seek an interface tissue engineering method for simultaneously regenerating cartilage and subchondral bone. The purpose of this review was to analyzes these two tissues on the characteristics from the surface of articular cartilage to subchondral bone such as the chemical composition, microstructure mechanical characteristics, bioelectrical characteristics, and physiological metabolism.

Key words: Cartilage, Tissue engineering

Xiang Li, Peiliang Fu. Advances in gradient for osteochondral interface tissue[J]. Chinese Journal of Joint Surgery(Electronic Edition), 2020, 14(06): 722-728.

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References 43

[1]	Di Luca A, Van Blitterswijk C, Moroni L. The osteochondral interface as a gradient tissue: from development to the fabrication of gradient scaffolds for regenerative medicine [J]. Birth Defects Res C Embryo Today, 2015, 105(1): 34-52.
[2]	Khorshidi S, Karkhaneh A. A review on gradient hydrogel/fiber scaffolds for osteochondral regeneration [J]. J Tissue Eng Regen Med, 2018, 12(4): 1974-1990.
[3]	Mohabatpour F, Karkhaneh A, Sharifi A M. A hydrogel/fiber composite scaffold for chondrocyte encapsulation in cartilage tissue regeneration [J]. RSC Advances, 2016, 6(86): 83135-83145.
[4]	Longley R, Ferreira AM, Gentile P. Recent approaches to the manufacturing of biomimetic multi-phasic scaffolds for osteochondral regeneration [J]．Int J Mol Sci, 2018, 19(6): 1-17.
[5]	Baumann CA, Hinckel BB, Bozynski CC, et al. Articular cartilage: structure and restoration [M]. 2nd ed. Germany: Springer，2019: 3-24.
[6]	Mansfield JC, Bell JS, Winlove CP. The micromechanics of the superficial zone of articular cartilage [J]. Osteoarthritis Cartilage, 2015, 23(10): 1806-1816.
[7]	Quinn TM, Hauselmann HJ, Shintani N, et al. Cell and matrix morphology in articular cartilage from adult human knee and ankle joints suggests depth-associated adaptations to biomechanical and anatomical roles [J]. Osteoarthritis Cartilage, 2013, 21(12): 1904-1912.
[8]	Farooqi AR, Bader R, van Rienen U. Numerical study on electromechanics in cartilage tissue with respect to its electrical properties[J]. Tissue Eng Part B Rev, 2019, 25(2): 152-166.
[9]	Ng HY, Lee K-XA, Shen YF. Articular cartilage: structure, composition, injuries and repair [J/OL]. JSM Bone and Joint Dis, 2017，1(2): 1010. URL
[10]	Panadero J, Lanceros-Mendez S, Ribelles J G. Differentiation of mesenchymal stem cells for cartilage tissue engineering: individual and synergetic effects of three-dimensional environment and mechanical loading [J]. Acta Biomater, 2016, 15(33):1-12.
[11]	DiDomenico CD, Lintz M, Bonassar LJ. Molecular transport in articular cartilage-what have we learned from the past 50 years? [J]. Nat Rev Rheumatol, 2018, 14(7): 393-403.
[12]	Oinas J, Ronkainen AP, Rieppo L, et al. Composition, structure and tensile biomechanical properties of equine articular cartilage during growth and maturation [J]. Sci Rep, 2018, 8(1): 1-12.
[13]	Gao L-L, Zhang C-Q, Gao H, et al. Depth and rate dependent mechanical behaviors for articular cartilage: experiments and theoretical predictions [J]. Mater Sci Eng C Mater Biol Appl, 2014, 1(38):244-251.
[14]	Camarero-Espinosa S, Rothen-Rutishauser B, Foster EJ, et al. Articular cartilage: from formation to tissue engineering [J]. Biomater Sci, 2016, 4(5): 734-767.
[15]	Sakai N, Hashimoto C, Yarimitsu S, et al. A functional effect of the superficial mechanical properties of articular cartilage as a load bearing system in a sliding condition [J]. Biosurf Biotribol, 2016, 2(1): 26-39.
[16]	Puhakka P, Te Moller N, Afara I, et al. Estimation of articular cartilage properties using multivariate analysis of optical coherence tomography signal [J]. Osteoarthritis cartilage, 2015, 23(12): 2206-2213.
[17]	Milner PI, Gibson JS, Wilkins RJ. Cellular physiology of articular cartilage in health and disease[M]. 2nd ed. The British: INTECH Open Access Publisher, 2012：101-105.
[18]	Kogan G, Šoltés L. Hyaluronan-a high Molar mass messenger reporting on the status of synovial joints[M]. First ed. New York: Nova Science Publishers, 2010：121-133.
[19]	Hossain MS, Bergstrom D, Chen X. Modelling and simulation of the chondrocyte cell growth, glucose consumption and lactate production within a porous tissue scaffold inside a perfusion bioreactor [J]. Biotechnol Rep (Amst), 2015, 8(5):55-62.
[20]	Lotz M, Loeser RF. Effects of aging on articular cartilage homeostasis [J]. Bone, 2012, 51(2): 241-248.
[21]	Becher C, Ricklefs M, Willbold E, et al. Electromechanical Assessment of Human Knee Articular Cartilage with Compression-Induced Streaming Potentials[J]. Cartilage, 2016, 7(1): 62-69.
[22]	Madi K, Staines KA, Bay BK, et al. In situ characterization of nanoscale strains in loaded whole joints via synchrotron X-ray tomography[J]. Nat Biomed Eng, 2020, 4(3): 343-354.
[23]	Das Gupta S, Finnilä MAJ, Karhula SS, et al. Raman microspectroscopic analysis of the tissue-specific composition of the human osteochondral junction in osteoarthritis: a pilot study[J]. Acta Biomater, 2020, 1(106):145-155.
[24]	Zhang T, Wu C, Li B, et al. Linking the SO2 emission of cement plants to the sulfur characteristics of their limestones: a study of 80 NSP cement lines in China[J]. J Clean Prod, 2019, 20(220):200-211.
[25]	Zhang Y, Wang F, Tan H, et al. Analysis of the mineral composition of the human calcified cartilage zone [J]. Int J Med Sci, 2012, 9(5): 353.
[26]	Jaroszewicz J, Kosowska A, Hutmacher D, et al. Insight into characteristic features of cartilage growth plate as a physiological template for bone formation[J]. J Biomed Mater Res A, 2016, 104(2): 357-366.
[27]	Arkill K, Winlove C. Solute transport in the deep and calcified zones of articular cartilage[J]. Osteoarthritis Cartilage, 2008, 16(6): 708-714.
[28]	Taheri S, Winkler T, Schenk L S, et al. Developmental transformation and reduction of connective cavities within the subchondral bone[J]. Int J Mol Sci, 2019, 20(3):1-13.
[29]	Nielsen AW, Klose-Jensen R, Hartlev LB, et al. Age-related histological changes in calcified cartilage and subchondral bone in femoral heads from healthy humans[J]. Bone, 2019, 129:1-8.
[30]	Florencio-Silva R, Sasso GRd S, Sasso-Cerri E, et al. Biology of bone tissue: structure, function, and factors that influence bone cells[J]．Biomed Res Int, 2015, 2015:1-13.
[31]	Feng X. Chemical and biochemical basis of cell-bone matrix interaction in health and disease[J]. Curr ChemBiol, 2009, 3(2): 189-196.
[32]	Pal S. Mechanical properties of biological materials[M]. 2nd ed. Germany: Springer, 2014: 23-40.
[33]	Bandyopadhyay S. Bone as a collagen-hydroxyapatite composite and its repair[J]．Trends Biomater Artif Organs, 2008, 22(2): 116-124.
[34]	Ni Q, Bredbenner T. Characterization of human cortical and trabecular bone structural change [C/OL] //NMR and Micro-CT-Summer Bioengineering Conference, Fajardo, Puerto Rico: American Society of Mechanical Engineers, 2012. doi：org/10.1115/SBC2012-80336.
[35]	Marrella A, Lee TY, Lee DH, et al. Engineering vascularized and innervated bone biomaterials for improved skeletal tissue regeneration [J]. Mater Today (Kidlington), 2018, 21(4): 362-376.
[36]	Carlier A, Geris L, van Gastel N, et al. Oxygen as a critical determinant of bone fracture healing-a multiscale model [J]. J Theor Biol, 2015, 21(365):247-264.
[37]	Karner CM, Long F. Glucose metabolism in bone [J]. Bone, 2018, 10(115):2-7.
[38]	Cerrolaza M, Duarte V, Garzón D. Analysis of bone remodeling under piezoelectricity effects using boundary elements[J]．J Bionic Eng, 2017, 14(4): 659-671.
[39]	Jacob J, More N, Kalia K, et al. Piezoelectric smart biomaterials for bone and cartilage tissue engineering[J]. Inflamm Regen, 2018, 38(1): 1-11.
[40]	Bertassoni LE, Coelho PG. Preface: engineering mineralized and load-bearing tissues: progress and challenges[J]. Adv Exp Med Biol, 2015, 1(881):5-7.
[41]	Verhaegen J, Clockaerts S, Van O G J, et al. TruFit Plug for repair of osteochondral defects-where is the evidence? Systematic review of literature[J]. Cartilage, 2015, 6(1): 12-19.
[42]	Fini M, Pagani S, Giavaresi G, et al. Functional tissue engineering in articular cartilage repair: is there a role for electromagnetic biophysical stimulation？[J]．Tissue Eng Part B Rev, 2013, 19(4): 353-367.
[43]	Kon E, Filardo G, Perdisa F, et al. Clinical results of multilayered biomaterials for osteochondral regeneration [J]. J Exp Orthop, 2014, 1(1):1-8.

类别	特点
组成成分	①胶原纤维直径与深度成正比，胶原纤维含量与深度成反比 ②软骨细胞数量与深度成反比 ③水含量与深度成反比 ④PG含量与深度成正比
机械特征	①压力模量与深度成正比 ②张力模量与深度成反比 ③机械性能与施加压力成正比
微观结构	①渗透率与深度成反比
生理代谢	①氧分压与深度成反比 ②葡萄糖浓度梯度与深度成反比 ③三种氧分压变化理论
生物电学	①软骨组织的电学性质存在三种理论，即流动电位、扩散电位和压电电位 ②Ⅱ型胶原纤维产生电信号 ③Ⅱ型胶原蛋白的压电系数比Ⅰ型胶原蛋白的压电系数低 ④软骨的压电电位低于骨组织的压电电位

类别	特点
组成成分	①胶原纤维直径与深度成正比，胶原纤维含量与深度成反比 ②软骨细胞数量与深度成反比 ③水含量与深度成反比 ④PG含量与深度成正比
机械特征	①压力模量与深度成正比 ②张力模量与深度成反比 ③机械性能与施加压力成正比
微观结构	①渗透率与深度成反比
生理代谢	①氧分压与深度成反比 ②葡萄糖浓度梯度与深度成反比 ③三种氧分压变化理论
生物电学	①软骨组织的电学性质存在三种理论，即流动电位、扩散电位和压电电位 ②Ⅱ型胶原纤维产生电信号 ③Ⅱ型胶原蛋白的压电系数比Ⅰ型胶原蛋白的压电系数低 ④软骨的压电电位低于骨组织的压电电位

类别	特点
组成成分	①含少量肥大软骨细胞，体积是其他区域的20倍，主要分泌X型胶原蛋白，具有轻微软骨组织特征 ②发现ALP，具有骨组织特征
机械特征	①钙化软骨弹性模量小于软骨下骨，受损时易首先出现微骨折
微观结构	①CCL也具有孔隙，孔径范围20～30 μm，孔隙率为84%～88%，其厚度为3～5 μm
生理代谢	①具有类似半透膜的功能 ②溶质运输在该层减少，但对低分子量溶质也具有一定的渗透性 ③CCL层具有动态变化的性质，CCL和SBB厚度的比例相对恒定

类别	特点
组成成分	①含少量肥大软骨细胞，体积是其他区域的20倍，主要分泌X型胶原蛋白，具有轻微软骨组织特征 ②发现ALP，具有骨组织特征
机械特征	①钙化软骨弹性模量小于软骨下骨，受损时易首先出现微骨折
微观结构	①CCL也具有孔隙，孔径范围20～30 μm，孔隙率为84%～88%，其厚度为3～5 μm
生理代谢	①具有类似半透膜的功能 ②溶质运输在该层减少，但对低分子量溶质也具有一定的渗透性 ③CCL层具有动态变化的性质，CCL和SBB厚度的比例相对恒定

类别	特点
组成成分	①骨组织含有多种不同的细胞：成骨细胞、破骨细胞、骨细胞、软骨细胞、内皮细胞和MSC ②骨组织中最丰富的细胞是骨细胞 ③ SBB中HA含量最多
机械特征	①纵向上的抗拉强度比抗压缩作用弱 ②横向方向抗拉强度和抗压强度有所减弱，小于纵向抗拉强度和抗压强度
微观结构	①孔隙率与深度成正比，与致密度和体积分数成反比 ②渗透性与细胞密度成正比
生理代谢	①软骨下骨区的氧分压低于软骨区 ②葡萄糖是细胞重要的能量来源和主要营养物质
生物电学	①骨组织的主要成分是I型胶原，压电电位主要由I型胶原胶原纤维诱导 ②骨骼产生的电流比软骨强

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