Effects of 3D printed surface topography and normal force on implant expulsion.

Amanda Heimbrook, Cambre N. Kelly, K. Gall
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引用次数: 3

Abstract

3D printing is a critical method for manufacturing metallic implants as it enables direct fabrication of intricate geometries and porous structures inaccessible to other manufacturing methods. Some common 3D printed porous structures are strut based (e.g. octet truss), triply periodic minimal surfaces (TPMS) (e.g. gyroid) or randomized (e.g. stochastic). When designed to be on the surface of bone interfacing implants, the surface porous region impacts short-term adhesion and friction, ultimately affecting implant stability prior to and during long-term osseointegration. In many orthopedic procedures, expulsion resistance is an essential design requirement, to prevent the risk of the implant migrating from the implantation site. While expulsion tests are universal, they are a poorly understood method to examine the bone-implant interface in determining the performance of an orthopedic implant. In this foundational study, we examine the expulsion behavior of metallic samples in synthetic Sawbone with systematically varied surface topography at increasing applied normal forces. The applied normal force and size of the sample were shown to have the strongest influence on expulsion force followed by surface structure. Compared to a polished sample control, certain 3D printed surface structures are up to 10x more expulsion resistant and should be considered in implants where prevention of implant migration before and during osseointegration is critical. Nonlinear relationships were discovered that reveal "crossover" in expulsion resistance as a function of applied load revealing that the ranking of the relative expulsion resistance of different samples can depend on the normal force selected. This new fundamental understanding has broad implications on both the design and potential standardized regulatory testing of textured orthopedic implants with tailored topologies.
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3D打印表面形貌和法向力对种植体排出的影响。
3D打印是制造金属植入物的关键方法,因为它可以直接制造复杂的几何形状和其他制造方法无法实现的多孔结构。一些常见的3D打印多孔结构是基于支柱(例如八柱桁架),三周期最小表面(例如陀螺)或随机(例如随机)。当被设计在骨界面种植体的表面时,表面多孔区域会影响短期的粘附和摩擦,最终影响种植体在长期骨整合之前和期间的稳定性。在许多骨科手术中,抗排出性是一个基本的设计要求,以防止植入物从植入部位迁移的风险。虽然排出试验是通用的,但在确定骨科植入物的性能时,它们是一种检查骨-植入物界面的鲜为人知的方法。在这项基础研究中,我们研究了金属样品在合成锯骨中具有系统变化的表面形貌的排样行为,并增加了施加的法向力。结果表明,施加的法向力和样品尺寸对排渣力的影响最大,其次是表面结构。与抛光样品对照相比,某些3D打印表面结构的抗排出性高出10倍,在植入物中应该考虑在骨整合之前和期间防止植入物迁移。研究发现,非线性关系揭示了排阻作为施加载荷的函数的“交叉”,表明不同样品的相对排阻的排名可能取决于所选择的法向力。这一新的基本认识对具有定制拓扑结构的纹理骨科植入物的设计和潜在的标准化监管测试具有广泛的意义。
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