混合技术对丙烯酸骨水泥物理性能的影响。

Influence of mixing techniques on the physical properties of acrylic bone cement.

作者信息

Dunne N J, Orr J F

机构信息

School of Mechanical and Manufacturing Engineering, Dublin City University, Glasnevin, Republic of Ireland.

出版信息

Biomaterials. 2001 Jul;22(13):1819-26. doi: 10.1016/s0142-9612(00)00363-x.

DOI:10.1016/s0142-9612(00)00363-x

PMID:11396886

Abstract

Palacos R bone cement was prepared using three commercially available mixing techniques, first generation, second generation and third generation, to determine the mechanical properties and porosity contents of the bone cement. The compressive strengths, bending strengths and flexural moduli were expressed as a function of void content. The volume of pores within the cement structure was found to be a contributing factor to the physical properties of acrylic bone cement. The lower the volume of voids in the cement the better the compressive and flexural properties, hence stronger bone cement. It was found that the best results were obtained from cement that had been mixed using the Mitab Optivac or Summit HiVac Syringe systems at a reduced pressure level of between -72 and -86 kPa below atmospheric pressure, resulting in cement of porosity 1.44-3.17%; compressive strength 74-81 MPa; flexural modulus 2.54-2.60 GPa; and flexural strength 65-73 MPa.

摘要

使用三种市售混合技术（第一代、第二代和第三代）制备帕拉科斯R骨水泥，以确定骨水泥的力学性能和孔隙率。抗压强度、抗弯强度和弯曲模量表示为孔隙率的函数。发现水泥结构内的孔隙体积是影响丙烯酸骨水泥物理性能的一个因素。水泥中的孔隙体积越低，抗压和抗弯性能越好，因此骨水泥越强。结果发现，使用米塔布Optivac或Summit HiVac注射器系统在低于大气压72至86 kPa的减压水平下混合的水泥效果最佳，得到的水泥孔隙率为1.44 - 3.17%；抗压强度为74 - 81 MPa；弯曲模量为2.54 - 2.60 GPa；抗弯强度为65 - 73 MPa。

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混合技术对丙烯酸骨水泥物理性能的影响。

Influence of mixing techniques on the physical properties of acrylic bone cement.

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