HISTOLOGICAL STRUCTURE AND CYTOCOMPATIBILITY OF NOVEL ACELLULAR BONE MATRIX SCAFFOLD_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

ZHAO Yanhong ^1,2 , YANG Qiang ³ , PENG Jiang ¹ , GUO Quanyi ¹ , XIA Qun ³ , MA Xinlong ³ , XU Baoshan ³ , ZHAO Bin ¹ , ZHANG Li ¹ , WU Yaohong ³ , LIU Yue ¹ , XU Wenjing ¹ , LU Shibi ¹

1Institute of Orthopedics, General Hospital of Chinese PLA, Beijing, 100853, P.R.China;;
2Department of Orthodontics, Stomatological Hospital of Tianjin Medical University;;
3Department of Spine Surgery, Tianjin Hospital. Corresponding author: LU Shibi, E-mail: shibilu301@gmail.com;;
PENG Jiang, E-mail: pengjdxx@126.com;

Corresponding author：

Keywords：

Tissue engineered bone; Acellular bone matrix; Cytocompatibility; Canine

DOI：

10.7507/1002-1892.20130173

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Objective To observe the histological structure and cytocompatibility of novel acellular bone matrix (ACBM) and to investigate the feasibility as a scaffold for bone tissue engineering. Methods Cancellous bone columns were harvested from the density region of 18-24 months old male canine femoral head, then were dealt with high-pressure water washing, degreasing, and decellularization with Trixon X-100 and sodium deoxycholate to prepare the ACBM scaffold. The scaffolds were observed by scanning electron microscope (SEM); HE staining, Hoechst 33258 staining, and sirius red staining were used for histological analysis. Bone marrow mesenchymal stem cells (BMSCs) from canine were isolated and cultured with density gradient centrifugation; the 3rd passage BMSCs were seeded onto the scaffold. MTT test was done to assess the cytotoxicity of the scaffolds. The proliferation and differentiation of the cells on the scaffold were observed by inverted microscope, SEM, and live/dead cell staining method. Results HE staining and Hoechst 33258 staining showed that there was no cell fragments in the scaffolds; sirius red staining showed that the ACBM scaffold was stained crimson or red and yellow alternating. SEM observation revealed a three dimensional interconnected porous structure, which was the microstructure of normal cancellous bone. Cytotoxicity testing with MTT revealed no significant difference in absorbance (A) values between different extracts (25%, 50%, and 100%) and H-DMEM culture media (P gt; 0.05), indicating no cytotoxic effect of the scaffold on BMSCs. Inverted microscope, SEM, and histological analysis showed that three dimensional interconnected porous structure of the scaffold supported the proliferation and attachment of BMSCs, which secreted abundant extracellular matrices. Live/dead cell staining results of cell-scaffold composites revealed that the cells displaying green fluorescence were observed. Conclusion Novel ACBM scaffold can be used as an alternative cell-carrier for bone tissue engineering because of thoroughly decellularization, good mircostructure, non-toxicity, and good cytocompatibility.

Citation： ZHAO Yanhong,YANG Qiang,PENG Jiang,GUO Quanyi,XIA Qun,MA Xinlong,XU Baoshan,ZHAO Bin,ZHANG Li,WU Yaohong,LIU Yue,XU Wenjing,LU Shibi. HISTOLOGICAL STRUCTURE AND CYTOCOMPATIBILITY OF NOVEL ACELLULAR BONE MATRIX SCAFFOLD. Chinese Journal of Reparative and Reconstructive Surgery, 2013, 27(7): 781-785. doi: 10.7507/1002-1892.20130173 Copy

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11.	Spector M. Biomaterials-based tissue engineering and regenerative medicine solutions to musculoskeletal problems. Swiss Med Wkly, 2007, 137 Suppl 155: 157S-165S.
12.	Böer U, Lohrenz A, Klingenberg M, et al. The effect of detergent-based decellularization procedures on cellular proteins and immunogenicity in equine carotid artery grafts. Biomaterials, 2011, 32(36): 9730-9737.
13.	Zhao Y, Zhang Z, Wang J, et al. Abdominal hernia repair with a decellularized dermal scaffold seeded with autologous bone marrow-derived mesenchymal stem cells. Artif Organs, 2012, 36(3): 247-255.
14.	Böer U, Spengler C, Klingenberg M, et al. Cytotoxic effects of polyhexanide on cellular repopulation and calcification of decellularized equine carotids in vitro and in vivo. Int J Artif Organs, 2013, 36(3): 184-194.
15.	Ye X, Wang H, Zhou J, et al. The effect of Heparin-VEGF multilayer on the biocompatibility of decellularized aortic valve with platelet and endothelial progenitor cells. PLoS One, 2013, 8(1): e54622.
16.	Syedain ZH, Bradee AR, Kren S, et al. Decellularized tissue-engineered heart valve leaflets with recellularization potential. Tissue Eng Part A, 2013, 19(5-6): 759-769.
17.	孙新君, 王正国, 朱佩芳, 等. 脱细胞骨基质材料的特性及生物安全性观察. 中华创伤杂志, 2005, 21(11): 833-837.
18.	孙新君, 王正国, 朱佩芳, 等. 重组人骨形态发生蛋白2／脱细胞骨基质材料复合移植修复兔骨缺损的研究. 中华实验外科杂志, 2005, 22(3): 287-289.
19.	张旗涛, 姚猛, 于友, 等. 同种异体脱细胞骨的生物力学性质及其临床应用. 中华小儿外科杂志, 2004, 25(2): 172-175.
20.	Sun XJ, Peng W, Yang ZL, et al. Heparin-chitosan-coated acellular bone matrix enhances perfusion of blood and vascularization in bone tissue engineering scaffolds. Tissue Eng Part A, 2011, 17(19-20): 2369-2378.

1. Datta P, Chatterjee J, Dhara S. Phosphate functionalized and lactic acid containing graft copolymer: synthesis and evaluation as biomaterial for bone tissue engineering applications. J Biomater Sci Polym Ed, 2013, 24(6): 696-713.
2. Ba Linh NT, Min YK, Lee BT. Hybrid hydroxyapatite nanoparticles-loaded PCL/GE blend fibers for bone tissue engineering. J Biomater Sci Polym Ed, 2013, 24(5): 520-538.
3. Toskas G, Cherif C, Hund RD, et al. Chitosan(PEO)/silica hybrid nanofibers as a potential biomaterial for bone regeneration. Carbohydr Polym, 2013, 94(2): 713-722.
4. Ariani MD, Matsuura A, Hirata I, et al. New development of carbonate apatite-chitosan scaffold based on lyophilization technique for bone tissue engineering. Dent Mater J, 2013, 32(2): 317-325.
5. Hutmacher DW. Scaffolds in tissue engineering bone and cartilage. Biomaterials, 2000, 21(24): 2529-2543.
6. 张建党, 卢世璧, 袁玫, 等. 关节软骨源性微载体与软骨细胞的体外相容性. 中华创伤骨科杂志, 2005, 7(9): 844-847.
7. 杨强, 彭江, 卢世璧, 等. 新型脱细胞软骨基质三维多孔支架的制备. 中国修复重建外科杂志, 2008, 22(3): 359-363.
8. 杨强, 彭江, 卢世璧, 等. 新型脱细胞骨基质材料的制备及理化评估. 中国组织工程研究与临床康复杂志, 2011, 15(38): 7041-7044.
9. Yang Q, Peng J, Guo Q, et al. A cartilage ECM-derived 3-D porous acellular matrix scaffold for in vivo cartilage tissue engineering with PKH26-labeled chondrogenic bone marrow-derived mesenchymal stem cells. Biomaterials, 2008, 29(15): 2378-2387.
10. 许海委, 徐宝山, 杨强, 等. 新型一体化纤维环-髓核双相支架的制备与评估. 中国修复重建外科杂志, 2013, 27(4): 475-480.
11. Spector M. Biomaterials-based tissue engineering and regenerative medicine solutions to musculoskeletal problems. Swiss Med Wkly, 2007, 137 Suppl 155: 157S-165S.
12. Böer U, Lohrenz A, Klingenberg M, et al. The effect of detergent-based decellularization procedures on cellular proteins and immunogenicity in equine carotid artery grafts. Biomaterials, 2011, 32(36): 9730-9737.
13. Zhao Y, Zhang Z, Wang J, et al. Abdominal hernia repair with a decellularized dermal scaffold seeded with autologous bone marrow-derived mesenchymal stem cells. Artif Organs, 2012, 36(3): 247-255.
14. Böer U, Spengler C, Klingenberg M, et al. Cytotoxic effects of polyhexanide on cellular repopulation and calcification of decellularized equine carotids in vitro and in vivo. Int J Artif Organs, 2013, 36(3): 184-194.
15. Ye X, Wang H, Zhou J, et al. The effect of Heparin-VEGF multilayer on the biocompatibility of decellularized aortic valve with platelet and endothelial progenitor cells. PLoS One, 2013, 8(1): e54622.
16. Syedain ZH, Bradee AR, Kren S, et al. Decellularized tissue-engineered heart valve leaflets with recellularization potential. Tissue Eng Part A, 2013, 19(5-6): 759-769.
17. 孙新君, 王正国, 朱佩芳, 等. 脱细胞骨基质材料的特性及生物安全性观察. 中华创伤杂志, 2005, 21(11): 833-837.
18. 孙新君, 王正国, 朱佩芳, 等. 重组人骨形态发生蛋白2／脱细胞骨基质材料复合移植修复兔骨缺损的研究. 中华实验外科杂志, 2005, 22(3): 287-289.
19. 张旗涛, 姚猛, 于友, 等. 同种异体脱细胞骨的生物力学性质及其临床应用. 中华小儿外科杂志, 2004, 25(2): 172-175.
20. Sun XJ, Peng W, Yang ZL, et al. Heparin-chitosan-coated acellular bone matrix enhances perfusion of blood and vascularization in bone tissue engineering scaffolds. Tissue Eng Part A, 2011, 17(19-20): 2369-2378.

Chinese Journal of Reparative and Reconstructive Surgery

HISTOLOGICAL STRUCTURE AND CYTOCOMPATIBILITY OF NOVEL ACELLULAR BONE MATRIX SCAFFOLD

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