骨髓间充质干细胞与纳米羟基磷灰石支架材料的体外相容性研究
In vitro biocompatibility of bone marrow mesenchymal stem cells and nano-hydroxyapatite scaffold
目的 探讨兔骨髓间充质干细胞(rBMSCs)与纳米羟基磷灰石(nano-HA)支架材料的相容性,进一步验证nano-HA材料作为骨组织工程支架材料的可行性。 方法 将rBMSCs与nano-HA支架材料在体外复合培养,通过倒置显微镜、扫描电镜观察细胞与材料的复合情况,用MTT法、碱性磷酸酶活性检测法检测材料对细胞增殖、分化的影响。 结果 rBMSCs可以在nano-HA支架材料表面及孔隙中良好的黏附、迁移、增殖和分化,复合培养5 d后nano-HA支架材料对rBMSCs的增殖分化表现出一定的促进作用。 结论 rBMSCs与nano-HA支架材料具有良好的生物相容性, nano-HA支架材料可以作为rBMSCs良好的载体。
Objective To assess the compatibility of rabbit bone marrow mesenchymal stem cells(rBMSCs) with nano-hydroxyapatite(nano-HA) scaffold,and to verify the feasibility of nano-HA material as scaffold material of bone tissue engineering. Methods rBMSCs were cultured on nano-HA scaffold in vitro. Inverted microscope and scanning electron microscope were used to observe the morphologic features of cultured cells attached on the scaffold, as well, cell proliferation and differentiation under the influence of the material were detected by MTT and ALP methods. Results On the nano-HA scaffold, rBMSCs attached and survived well. Scaffold did not interfere with the proliferation and differentiation of the seeded rBMSCs, which indicated that Nano-HA scaffold was favourable for the survival and differentiation of rBMSCs in vitro condition. Conclusions Nano-HA material can be taken as the ideal rBMSCs scaffold for its excellent biocompatibility.
Bone marrow mesenchymal stem cells(rBMSCs) / Nano-hydroxyapatite / Biocompatibility
[1] 蓝旭,杨志明,罗静聪,等.不同保存方法对生物衍生骨支架材料细胞相容性的影响
[J].中国修复重建外科杂志,2003,11(16):209-213.
[2] Jayasuriya AC,Shah C,Ebraheim NA,et a1.Acceleration of biomimetic mineralization to apply in bone regeneration
[J].Biomed Mater,2008,3(1):015003 (6pp).
[3] 许宇霞,邓展生,李宝军,等.纳米羟基磷灰石对人骨髓基质干细胞体外成骨活性的影响
[J].中国组织工程研究与临床康复,2007,11(31):6183-6186.
[4] 赵彦涛,张玉梅,宁芳,等.两种纳米晶羟基磷灰石的细胞相容性比较
[J].现代口腔医学杂志,2007,21(1):16-19.
[5] 赵瑾,袁晓燕,姚康德.组织工程多孔支架制备技术进展
[J].化工进展,2002;21(9): 644-648.
[6] 谭延斌,王毅,杨庆铭,等.纳米级羟基磷灰石梯度涂层对成骨细胞表型因子表达的影响
[J].上海第二医科大学学报,2005,25(4):382-384.
[7] Liao SS,Cui FZ.In vitro and in vivo degradation of the mineralized collagen - based composite scaffold:nanohydroxyapatite/collagen/polyZ(L-lactide)
[J].Tissue Engineering,2004,10(1):72-80.
[8] Liao SS, Guan K,Cui FZ,et a1.Lumbar Spinal fusion with a mineralized collagen matrix and rhBMP-2 in a rabbit model
[J].Spine,2003,28(17):1954-1960.
[9] Kim IY,Seo SJ,Moon HS,et al.Chitosan and its derivatives for tissue engineering applications
[J].Biotechnology Advance,2008,26(1):1-21.
[10]Xin X,Hussain M,Mao JJ.Continuing differentiation of human mesenchymal stem cells and induced chondrogenic and osteogenic lineages in electrospun PLGA nanofiber scaffold
[J].Biomaterials,2007,28(2):316-325.
[11] Ginebra MP,Driessens FC,Planell JA.Effect of the particle size on the micro and nano structural features of a calcium phosphate cement:a kinetic analysis
[J].Biomaterials,2004,25(17):3453-3462.
[12] Ambrosio AM,Sahota JS,Khan Y,et al.A novel amorphous calcium phosphate polymer ceramic for bone repair:I.Synthesis and characterization
[J].Biomedical Material Research,2001,58(3):295-301.
[13]Marra KG,Szem JW,Kumta PN,et al.In vitro analysis of biodegradable polymer blend/hydroxyapatite composites for bone tissue engineering
[J].Biomedical Material Research,1999,47(3):324-335.
[14] Kang MI,Lee WY,OH KW,et al.The short-term changes of bone mineral metabolism following bone marrow transplantation
[J].Bone,2000,26(3):275-279.
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