Accuracy and efficiency of finite element head models: The role of finite element formulation and material laws

IF 2.2 4区 医学 Q3 ENGINEERING, BIOMEDICAL International Journal for Numerical Methods in Biomedical Engineering Pub Date : 2024-07-24 DOI:10.1002/cnm.3851
Marcos S. Gomes, Gustavo P. Carmo, Mariusz Ptak, Fábio A. O. Fernandes, Ricardo J. Alves de Sousa
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Abstract

Traumatic brain injury is a significant problem worldwide. In the United States of America, around 1.7 million cases are documented annually, displaying the need for a deeper understanding of the effects on the human brain. The tests required for this assessment are very complex. Tests on cadavers may raise serious ethical questions, and in vivo crash tests are not viable. In this context, there is a great need to developing finite element head models (FEHM) to study the biomechanics of the tissues when submitted to a certain impact or acceleration/deceleration scenario. An excellent compromise between accuracy and CPU efficiency is always desirable for a FEHM, For this reason, this work focuses on the improvement of an existing head model, including the study of the behavior of the brain using distinct finite element types. The finite element type and formulation is of utmost importance for the general accuracy and efficiency of the models. Several validations were performed, comparing the simulation results against experimental data. The simulations with hexahedral elements, under specific conditions, obtained more accurate results with a lower computational cost. Using hexahedrals, a comparison was also performed using two material characterizations with more than 10 years apart, using the latest finite element head model validation experiment. Overall, the newer material model displays a less stiff response, although its implementation must always depend on the overall purpose of the model it is being applied to.

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有限元头模型的精度和效率:有限元配方和材料定律的作用。
创伤性脑损伤是一个全球性的重大问题。在美国,每年约有 170 万例记录在案,这表明有必要深入了解脑外伤对人脑的影响。这种评估所需的测试非常复杂。在尸体上进行测试可能会引发严重的伦理问题,而活体碰撞测试又不可行。在这种情况下,亟需开发头部有限元模型(FEHM)来研究组织在受到特定撞击或加速/减速情况下的生物力学。因此,这项工作的重点是改进现有的头部模型,包括使用不同的有限元类型研究大脑的行为。有限元类型和公式对模型的总体精度和效率至关重要。我们进行了多次验证,将模拟结果与实验数据进行比较。在特定条件下,使用六面体元素的模拟结果更精确,计算成本更低。在使用六面体的同时,还使用最新的有限元头模型验证实验,对相隔 10 多年的两种材料特性进行了比较。总体而言,较新的材料模型显示出较小的刚性响应,尽管其实施必须始终取决于所应用模型的总体目的。
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来源期刊
International Journal for Numerical Methods in Biomedical Engineering
International Journal for Numerical Methods in Biomedical Engineering ENGINEERING, BIOMEDICAL-MATHEMATICAL & COMPUTATIONAL BIOLOGY
CiteScore
4.50
自引率
9.50%
发文量
103
审稿时长
3 months
期刊介绍: All differential equation based models for biomedical applications and their novel solutions (using either established numerical methods such as finite difference, finite element and finite volume methods or new numerical methods) are within the scope of this journal. Manuscripts with experimental and analytical themes are also welcome if a component of the paper deals with numerical methods. Special cases that may not involve differential equations such as image processing, meshing and artificial intelligence are within the scope. Any research that is broadly linked to the wellbeing of the human body, either directly or indirectly, is also within the scope of this journal.
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