An open-access plug-in program for 3D modelling distinct material properties of cortical and trabecular bone.

BMC biomedical engineering Pub Date : 2022-09-24 DOI:10.1186/s42490-022-00065-z

Gregory R Roytman, Matan Cutler, Kenneth Milligan, Steven M Tommasini, Daniel H Wiznia

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Abstract

Background: Finite element modelling the material behavior of bone in-silico is a powerful tool to predict the best suited surgical treatment for individual patients.

Results: We demonstrate the development and use of a pre-processing plug-in program with a 3D modelling image processing software suite (Synopsys Simpleware, ScanIP) to assist with identifying, isolating, and defining cortical and trabecular bone material properties from patient specific computed tomography scans. The workflow starts by calibrating grayscale values of each constituent element with a phantom - a standardized object with defined densities. Using an established power law equation, we convert the apparent density value per voxel to a Young's Modulus. The resulting "calibrated" scan can be used for modeling and in-silico experimentation with Finite Element Analysis.

Conclusions: This process allows for the creation of realistic and personalized simulations to inform a surgeon's decision-making. We have made this plug-in program open and accessible as a supplemental file.

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一个开放访问的插件程序，用于3D建模不同的皮质骨和小梁骨的材料特性。

背景:硅骨材料行为的有限元建模是预测个体患者最适合的手术治疗的有力工具。结果:我们展示了一个预处理插件程序的开发和使用，该程序带有3D建模图像处理软件套件(Synopsys Simpleware, ScanIP)，以帮助从患者特定的计算机断层扫描中识别、分离和定义皮质和小梁骨材料的特性。工作流程开始于用一个幻影(一个具有定义密度的标准化对象)校准每个组成元素的灰度值。使用已建立的幂律方程，我们将每体素的表观密度值转换为杨氏模量。由此产生的“校准”扫描可用于建模和有限元素分析的硅实验。结论:该过程允许创建真实和个性化的模拟，以告知外科医生的决策。我们已经将这个插件程序作为一个补充文件打开并可访问。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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BMC biomedical engineering

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审稿时长

19 weeks