3D生物描绘孔结构可控钙磷硅基骨修复支架的生物力学性能
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国家重大科学研究计划(2011CB013300,2012CB933604),国家自然科学基金项目(81171707),上海市卫生系统重要疾病联合攻关项目(2013ZYJB0501),上海教委重点学科建设基金(J50206)


Biomechanical properties of calcium silicate/calcium phosphate cement scaffolds with controllable porous structure for bone repair by 3D bioplotting
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    摘要:

    目的 设计和制备新型钙磷硅基骨修复支架,研究其在不同外力作用下体外生物力学性能。方法 以自固化磷酸钙骨水泥(calcium phosphate cement, CPC)、介孔硅酸钙(mesporous calcium silicate,MCS)为原料,通过3D生物描绘技术构建孔径分别为350、500 μm的MCS/CPC复合支架。采用扫描电镜观察支架表面形貌;分别通过万能力学试验机和动态力学分析仪,考察具有不同孔道结构MCS/CPC支架的抗压力学性能和不同频率动态周期性载荷作用下的力学性能。结果 通过3D生物描绘技术能够实现对钙磷硅基骨修复支架内部孔道结构的可控制备。孔径为350 μm的MCS/CPC支架具有较高的抗压力学强度[(9.80±0.39) MPa]和抗压模量[(132.50±4.30) MPa];此外,载荷频率在1~100 Hz范围内,孔径为350 μm的支架具有较高的储能模量。结论 通过3D生物描绘技术制备的孔径为350 μm的MCS/CPC复合支架不仅具有规则的连通孔道,还具有较高的抗压力学性能,能在动态载荷作用下保持结构稳定,适合作为一种新型的骨缺损修复材料。

    Abstract:

    Objective To design and fabricate novel mesoporous calcium silicate/calcium phosphate cement (MCS/CPC) scaffolds for bone repair and investigate their in vitro biomechanical properties under different external forces. Methods MCS and CPC in certain proportion were mixed to form plotting material, and the composite MCS/CPC scaffolds with pore size of 350 μm and 500 μm were fabricated by 3D bioplotting technique, respectively. Surface topographies of the scaffolds were observed by scanning electron microscope (SEM). The compressive strength and mechanical properties of the scaffolds under dynamic cyclic loads at different frequencies were studied through universal mechanical testing machine and dynamic mechanical analysis instrument. Results MCS/CPC scaffolds with controllable macroporous structures could be fabricated by 3D bioplotting technique. Scaffolds with pore size of 350 μm had higher compressive strength [(9.8±0.39) MPa] and compressive modulus [(132.5±4.3) MPa]. In addition, at the loading frequency of 1-100 Hz, scaffolds with pore size of 350 μm had a higher storage modulus. ConclusionsMCS/CPC scaffolds with pore size of 350 μm fabricated by 3D bioplotting technique possess not only regular pore connectivity and high compressive strength, but also structural stability under dynamic loads, which are promising as novel biomaterials for bone repair.

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李翠笛,陈芳萍,王金武,戴尅戎,刘昌胜.3D生物描绘孔结构可控钙磷硅基骨修复支架的生物力学性能[J].医用生物力学,2015,30(4):350-354

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  • 收稿日期:2015-03-02
  • 最后修改日期:2015-04-09
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  • 在线发布日期: 2015-08-27
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