Axial tension/compression and torsional loading of diamond and gyroid lattice structures for biomedical implants: Simulation and experiment

IF 8.4

MATERIALS & DESIGN Pub Date : 2023-01-01 DOI:10.1016/j.matdes.2022.111585

Anatolie Timercan, Patrick Terriault, Vladimir Brailovski

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引用次数: 2

Abstract

Lattice structures are increasingly used in biomedical implants, notably intervertebral cages, requiring a better understanding of their behavior for the different types of loading they undergo during application. Strut-based diamond and sheet-based gyroid structures with porosity levels ranging from 50 to 80 % and an identical pore size of 750 μm were manufactured from Ti6Al4V alloy, tested experimentally and simulated numerically in axial tension/compression and in torsion to simulate flexion/extension, compression and rotation of the human spine. The manufactured structures were within 5 % of the targeted porosity. However, numerical simulations overestimated the experimental apparent (effective) stiffness and strength of the structures by an average of 25 %, likely due to the presence in them of manufacturing defects, especially in the higher porosity lattices. Experimental and numerical results showed that the structures have quasi-identical mechanical properties in compression and in tension. However, a comparison of the torsion and axial results indicated that conventional bulk material failure theories such as the von Mises limitation criterion do not apply to the apparent properties of lattice structures. Studied lattices exhibited adequate resistance for use in intervertebral cages, however their stiffness was greater than those of the vertebrae, while situated in the stiffness range of cortical bone.

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用于生物医学植入物的金刚石和陀螺晶格结构的轴向拉伸/压缩和扭转载荷:模拟和实验

晶格结构越来越多地用于生物医学植入物，特别是椎间笼，需要更好地了解其在应用过程中所承受的不同类型载荷的行为。以Ti6Al4V合金为材料，制备了孔隙度为50% ~ 80%、孔径为750 μm的基于支柱的金刚石和基于片状的旋转结构，并进行了轴向拉伸/压缩和扭转的实验和数值模拟，模拟了人体脊柱的弯曲/伸展、压缩和旋转。制造的结构在目标孔隙率的5%以内。然而，数值模拟将结构的实验表观(有效)刚度和强度平均高估了25%，这可能是由于其中存在制造缺陷，特别是在高孔隙率晶格中。实验和数值结果表明，该结构在压缩和拉伸条件下具有近似相同的力学性能。然而，扭转和轴向结果的比较表明，传统的块体材料破坏理论，如von Mises极限准则，并不适用于晶格结构的表观特性。所研究的晶格显示出足够的阻力用于椎间笼，但是它们的刚度大于椎骨，而位于皮质骨的刚度范围内。

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MATERIALS & DESIGN

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期刊介绍： Materials and Design is a multidisciplinary journal that publishes original research reports, review articles, and express communications. It covers a wide range of topics including the structure and properties of inorganic and organic materials, advancements in synthesis, processing, characterization, and testing, as well as the design of materials and engineering systems, and their applications in technology. The journal aims to integrate various disciplines such as materials science, engineering, physics, and chemistry. By exploring themes from materials to design, it seeks to uncover connections between natural and artificial materials, and between experimental findings and theoretical models. Manuscripts submitted to Materials and Design are expected to offer elements of discovery and surprise, contributing to new insights into the architecture and function of matter.