Laura H.J. Alberto , Saadman Alamgir , Jason A. Griggs , Michael D. Roach , Randal S. Williamson , Ravi Chandran , Matthew W. Priddy , Yuefeng J. Lu , Patrick F. Bergin , Yuanyuan Duan
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All models were exported to FEA software (ABAQUS) and subsequently to a fatigue analysis software (Fe-safe). A compressive 150 N load was applied at a 40° angle on the cap surface. A 15 Hz frequency was applied in the in silico cyclic test. The implant components had material properties of commercially pure grade 4 titanium (CPTi) and Titanium-6Aluminum-4Vanadium alloy (Ti64). Von Mises stress data, contour plots, and fatigue limits were collected and analyzed. EHC models exhibited higher peak stresses in implant components for both materials compared to IHC models. However, simulated bone support results showed the opposite trend, with higher stresses on IHCthan EHC models. The fatigue analysis revealed that assemblies with both designs exceeded ISO 14801:2016 number of cycles limits using Ti64, while CPTi groups exhibited comparatively lower worst life-repeats. 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引用次数: 0
摘要
颧骨种植体(ZIs)是作为一种无移植替代方法开发的,用于修复严重吸收的上颌骨。本研究旨在采用三维有限元分析 (FEA),使用 ISO 14801:2016 中定义的参数模拟外部六角种植体连接 (EHC) 和内部六角种植体连接 (IHC) 对 ZI 系统内应力分布和疲劳寿命的影响。在微型计算机断层扫描仪上扫描了两个 ZI 组件(Nobel Biocare 和 Noris Medical),并使用 Nrecon 软件进行了重建。三维模型由 Simpleware ScanIP Medical 软件生成。所有模型都被导出到有限元分析软件(ABAQUS),随后又导出到疲劳分析软件(Fe-safe)。以 40° 角在帽表面施加 150 N 的压缩载荷。模拟循环试验的频率为 15 赫兹。植入部件的材料属性为商业纯 4 级钛 (CPTi) 和钛-6 铝-4钒合金 (Ti64)。收集并分析了 Von Mises 应力数据、等值线图和疲劳极限。与 IHC 模型相比,两种材料的 EHC 模型都显示出种植体部件中更高的峰值应力。然而,模拟骨支撑结果显示出相反的趋势,IHC 模型的应力高于 EHC 模型。疲劳分析表明,两种设计的组件在使用 Ti64 时都超过了 ISO 14801:2016 的循环次数限制,而 CPTi 组的最差寿命循环次数相对较低。总之,采用 IHC 的 ZIs 在两种测试材料中的应力分布更均匀、更有利。在两种设计连接中,Ti64 都能延长使用寿命。
Influence of connection design and material properties on stress distribution and fatigue lifetime of zygomatic implants: A finite element analysis
Zygomatic implants (ZIs) were developed as a graftless alternative to rehabilitate severely reabsorbed maxillae. This study aims to employ three-dimensional finite element analysis (FEA) to simulate the impact of external hexagonal implant connection (EHC) and internal hexagonal implant connection (IHC) on the stress distribution and fatigue lifetime within the ZI systems using parameters defined in ISO 14801:2016. Two ZI assemblies (Nobel Biocare and Noris Medical) were scanned in a micro-CT scanner and reconstructed using Nrecon software. Three-dimensional models were generated by Simpleware ScanIP Medical software. All models were exported to FEA software (ABAQUS) and subsequently to a fatigue analysis software (Fe-safe). A compressive 150 N load was applied at a 40° angle on the cap surface. A 15 Hz frequency was applied in the in silico cyclic test. The implant components had material properties of commercially pure grade 4 titanium (CPTi) and Titanium-6Aluminum-4Vanadium alloy (Ti64). Von Mises stress data, contour plots, and fatigue limits were collected and analyzed. EHC models exhibited higher peak stresses in implant components for both materials compared to IHC models. However, simulated bone support results showed the opposite trend, with higher stresses on IHCthan EHC models. The fatigue analysis revealed that assemblies with both designs exceeded ISO 14801:2016 number of cycles limits using Ti64, while CPTi groups exhibited comparatively lower worst life-repeats. In conclusion, ZIs with IHC were found to have a more homogeneous and advantageous stress distribution within both materials tested. Ti64 demonstrates a prolonged service life for both design connections.
期刊介绍:
The Journal of the Mechanical Behavior of Biomedical Materials is concerned with the mechanical deformation, damage and failure under applied forces, of biological material (at the tissue, cellular and molecular levels) and of biomaterials, i.e. those materials which are designed to mimic or replace biological materials.
The primary focus of the journal is the synthesis of materials science, biology, and medical and dental science. Reports of fundamental scientific investigations are welcome, as are articles concerned with the practical application of materials in medical devices. Both experimental and theoretical work is of interest; theoretical papers will normally include comparison of predictions with experimental data, though we recognize that this may not always be appropriate. The journal also publishes technical notes concerned with emerging experimental or theoretical techniques, letters to the editor and, by invitation, review articles and papers describing existing techniques for the benefit of an interdisciplinary readership.