Osteogenesis effect of dynamic mechanical loading on MC3T3-E1 cells in three-dimensional printing biomimetic composite scaffolds_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

SONG Xiugang ^1,2,3 ,  LI Hui ¹ ,  LI Ruixin ³ , YUAN Qingxian ^3,4 , LIU Yingjie ^1,2,3 , CHENG Wei ^1,2,3 , ZHANG Xizheng ³

1. Department of Orthopedics, Tianjin Medical University General Hospital, Tianjin, 300052, P.R.China;
2. Department of Clinical Medicine of Graduate School, Tianjin Medical University, Tianjin, 300070, P.R.China;
3. Institute of Medical Equipment, Academy of Military Medical Science, Tianjin, 300161, P.R.China;
4. Department of Biomechanics of the Institute of Mechanics, Tianjin University of Technology, Tianjin, 300384, P.R.China;

Corresponding?author：

LI Hui, Email: ortholivea@126.com; LI Ruixin, Email: limxinxin@163.com

Keywords：

Silk fibroin; collagen; hydroxyapatite; MC3T3-E1 cells; mechanical loading

DOI：

10.7507/1002-1892.201711091

Video：

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Objective To observe the effect of dynamic mechanical loading on the proliferation, differentiation, and specific gene expression of MC3T3-E1 cells that on three-dimensional (3D) biomimetic composite scaffolds prepared by low temperature 3D printing technology combined with freeze-drying. Methods The silk fibroin, collagen type Ⅰ, and nano-hydroxyapatite (HA) were mixed at a mass ratio of 3∶9∶2 and were used to prepare the 3D biomimetic composite scaffolds via low temperature 3D printing technology combined with freeze-drying. General morphology of 3D biomimetic composite scaffold was observed. Micro-CT was used to observe the pore size and porosity of the scaffolds, and the water swelling rate, stress, strain, and elastic modulus were measured. Then, the MC3T3-E1 cells were seeded on the 3D biomimetic composite scaffolds and the cell-scaffold composites were randomly divided into 2 groups. The experimental group was subjected to dynamic mechanical loading (3 500 με, 1 Hz, 15 minutes per day); the control group was not subjected to loading treatment. After 7 days and 14 days, the cell-scaffold composites of 2 groups were harvested to observe the growth of cells on the scaffolds by HE staining and scanning electron microscope. And the gene and protein expressions of collagen type Ⅰ, BMP-2, and osteocalcin (OCN) were measured by real-time fluorescent quantitative PCR and Western blot. Results The 3D biomimetic composite scaffold was a white cubic grid. Micro-CT detection showed the pore network structure in the scaffold material with good pore connectivity. The diameters of large pore and micro-aperture were (506.37±18.63) μm and (62.14±17.35) μm, respectively. The porosity was 97.70%±1.37%, and the water absorption swelling rate was 1 341.97%±64.41%. Mechanical tests showed that the compression displacement of the scaffold was (0.376±0.004) mm, the compressive stress was (0.016±0.002) MPa, and the elastic modulus was (162.418±18.754) kPa when the scaffold was compressed to 10%. At 7 days and 14 days, HE staining and scanning electron microscope observation showed that the cells grew inside the scaffold, mainly distributed around the scaffold pore wall. The cells in experimental group were more than control group, and the cells morphology changed from shuttle to flat. There was no significant difference in the cell counting between 2 groups at 14 days after 200-fold microscopy (t=–2.024, P=0.080), but significant differences were found between 2 groups at different time points under different magnifications (P<0.05). Real-time fluorescent quantitative PCR showed that the mRNA relative expressions of collagen type Ⅰ and OCN in experimental group were significantly higher than those in control group at 7 and 14 days (P<0.05). However, the mRNA relative expression of BMP-2 showing no significant difference between 2 groups (P>0.05). The protein relative expressions of collagen type Ⅰ, BMP-2, and OCN in experimental group were significantly higher than those in control group at 7 and 14 days (P<0.05). Conclusion After dynamic mechanical loading, the expressions of BMP-2, collagen type Ⅰ, and OCN in MC3T3-E1 cells inoculated into 3D biomimetic composite scaffolds are significantly up-regulated, indicating that appropriate mechanical loads favor osteoblast differentiation of MC3T3-E1 cells.

Citation： SONG Xiugang, LI Hui, LI Ruixin, YUAN Qingxian, LIU Yingjie, CHENG Wei, ZHANG Xizheng. Osteogenesis effect of dynamic mechanical loading on MC3T3-E1 cells in three-dimensional printing biomimetic composite scaffolds. Chinese Journal of Reparative and Reconstructive Surgery, 2018, 32(4): 448-456. doi: 10.7507/1002-1892.201711091 Copy

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6.	Karageorgiou V, Kaplan D. Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials, 2005, 26(27): 5474-5491.
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14.	李瑞欣. 力學作用下微、納米 HA/CS 共混體系中微觀結構參數對成骨前體細胞 MC3T3-E1 生物學特性的影響. 北京: 中國人民解放軍軍事醫學科學院, 2012.
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20.	王亮. 力學拉伸應變對成骨細胞的影響及其作用機制的研究. 北京: 中國人民解放軍軍事醫學科學院, 2011.
21.	Schwetz V, Pieber T, Obermayer-Pietsch B. The endocrine role of the skeleton: background and clinical evidence. Eur J Endocrinol, 2012, 166(6): 959-967.
22.	孫健, 余優成, 顧章愉, 等. BMP-2 對大鼠骨髓間充質干細胞成骨作用的影響. 上海口腔醫學, 2011, 20(4): 352-357.
23.	Gunson D, Gropp KE, Varela A. Bone and Joints//Haschek and Rousseaux’s Handbook of Toxicologic Pathology. 3rd Ed. Boston: Academic Press, 2013: 2761-2858.
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25.	唐麗靈, 王遠亮, 谷俐, 等. 不同應變水平拉伸對成骨細胞生理功能的影響. 重慶大學學報 (自然科學版), 2003, 26(3): 67-70.

1. Hoque ME, Chuan YL, Pashby I. Extrusion based rapid prototyping technique: an advanced platform for tissue engineering scaffold fabrication. Biopolymers, 2012, 97(2): 83-93.
2. Wei G, Ma PX. Structure and properties of nano-hydroxyapatite/polymer composite scaffolds for bone tissue engineering. Biomaterials, 2004, 25(19): 4749-4757.
3. Vinatier C, Mrugala D, Jorgensen C, et al. Cartilage engineering: a crucial combination of cells, biomaterials and biofactors. Trends Biotechnol, 2009, 27(5): 307-314.
4. Gleeson JP, Plunkett NA, O’Brien FJ, Addition of hydroxyapatite improves stiffness, interconnectivity and osteogenic potential of a highly porous collagen-based scaffold for bone tissue regeneration. Addition of hydroxyapatite improves stiffness, interconnectivity and osteogenic potential of a highly porous collagen-based scaffold for bone tissue regeneration. Eur Cell Mater, 2010, 20: 218-230.
5. Wang X, Lou T, Zhao W, et al. The effect of fiber size and pore size on cell proliferation and infiltration in PLLA scaffolds on bone tissue engineering. J Biomater Appl, 2016, 30(10): 1545-1551.
6. Karageorgiou V, Kaplan D. Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials, 2005, 26(27): 5474-5491.
7. Baker RM, Tseng LF, Iannolo MT, et al. Self-deploying shape memory polymer scaffolds for grafting and stabilizing complex bone defects: A mouse femoral segmental defect study. Biomaterials, 2016, 76: 388-398.
8. Clarke B. Normal bone anatomy and physiology. Clin J Am Soc Nephrol, 2008, 3(Suppl 3): S131-S139.
9. 李東. 低溫3D打印技術聯合冷凍干燥法制備 SF/COL/nHA 仿生骨組織工程支架及其性能的研究. 天津: 天津醫科大學, 2016.
10. 張燕. 三維培養條件下動態載荷對 MC3T3-E1 成骨樣細胞生物學效應影響的研究. 北京: 中國人民解放軍軍事醫學科學院, 2010.
11. Sanz-Herrera JA, García-Aznar JM, Doblaré M. Micro-macro numerical modelling of bone regeneration in tissue engineering. Computer Methods in Applied Mechanics and Engineering, 2008, 197(s33-40): 3092-3107.
12. 張建明. 組織工程支架在流固場中力學環境的研究. 天津: 天津理工大學, 2013.
13. 徐曉瑩. 骨組織工程中細胞三維培養力學環境的研究. 北京: 中國人民解放軍軍事醫學科學院, 2009.
14. 李瑞欣. 力學作用下微、納米 HA/CS 共混體系中微觀結構參數對成骨前體細胞 MC3T3-E1 生物學特性的影響. 北京: 中國人民解放軍軍事醫學科學院, 2012.
15. Rodríguez JP, González M, Ríos S, et al. Cytoskeletal organization of human mesenchymal stem cells (MSC) changes during their osteogenic differentiation. J Cell Biochem, 2004, 93(4): 721-731.
16. 閆玉仙, 宋梅, 郭春, 等. 基底拉伸應變對小鼠三種骨組織細胞 BMP-2 mRNA 表達的影響. 中國老年學雜志, 2010, 30(21): 3092-3095.
17. An J, Yang H, Zhang Q, et al. Natural products for treatment of osteoporosis: The effects and mechanisms on promoting osteoblast-mediated bone formation. Life Sci, 2016, 147: 46-58.
18. Frost HM. Bone “mass” and the “mechanostat”: a proposal. Anat Rec, 1987, 219(1): 1-9.
19. Hempel U, M?ller S, Noack C, et al. Sulfated hyaluronan/collagenⅠmatrices enhance the osteogenic differentiation of human mesenchymal stromal cells in vitro even in the absence of dexamethasone. Acta Biomaterialia, 2012, 8(11): 4064-4072.
20. 王亮. 力學拉伸應變對成骨細胞的影響及其作用機制的研究. 北京: 中國人民解放軍軍事醫學科學院, 2011.
21. Schwetz V, Pieber T, Obermayer-Pietsch B. The endocrine role of the skeleton: background and clinical evidence. Eur J Endocrinol, 2012, 166(6): 959-967.
22. 孫健, 余優成, 顧章愉, 等. BMP-2 對大鼠骨髓間充質干細胞成骨作用的影響. 上海口腔醫學, 2011, 20(4): 352-357.
23. Gunson D, Gropp KE, Varela A. Bone and Joints//Haschek and Rousseaux’s Handbook of Toxicologic Pathology. 3rd Ed. Boston: Academic Press, 2013: 2761-2858.
24. Raggatt LJ, Partridge NC. Cellular and molecular mechanisms of bone remodeling. J Biol Chem, 2010, 285(33): 25103-25108.
25. 唐麗靈, 王遠亮, 谷俐, 等. 不同應變水平拉伸對成骨細胞生理功能的影響. 重慶大學學報 (自然科學版), 2003, 26(3): 67-70.

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Osteogenesis effect of dynamic mechanical loading on MC3T3-E1 cells in three-dimensional printing biomimetic composite scaffolds

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