Integrating material properties from magnetic resonance elastography into subject-specific computational models for the human brain

Q3 Engineering
Ahmed Alshareef , Andrew K. Knutsen , Curtis L. Johnson , Aaron Carass , Kshitiz Upadhyay , Philip V. Bayly , Dzung L. Pham , Jerry L. Prince , K.T. Ramesh
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引用次数: 9

Abstract

Advances in brain imaging and computational methods have facilitated the creation of subject-specific computational brain models that aid researchers in investigating brain trauma using simulated impacts. The emergence of magnetic resonance elastography (MRE) as a non-invasive mechanical neuroimaging tool has enabled in vivo estimation of material properties at low-strain, harmonic loading. An open question in the field has been how this data can be integrated into computational models. The goals of this study were to use a novel MRI dataset acquired in human volunteers to generate models with subject-specific anatomy and material properties, and then to compare simulated brain deformations to subject-specific brain deformation data under non-injurious loading. Models of five subjects were simulated with linear viscoelastic (LVE) material properties estimated directly from MRE data. Model predictions were compared to experimental brain deformation acquired in the same subjects using tagged MRI. Outcomes from the models matched the spatial distribution and magnitude of the measured peak strain components as well as the 95th percentile in-plane peak strains within 0.005 mm/mm and maximum principal strain within 0.012 mm/mm. Sensitivity to material heterogeneity was also investigated. Simulated brain deformations from a model with homogenous brain properties and a model with brain properties discretized with up to ten regions were very similar (a mean absolute difference less than 0.0015 mm/mm in peak strains). Incorporating material properties directly from MRE into a biofidelic subject-specific model is an important step toward future investigations of higher-order model features and simulations under more severe loading conditions.

Statement of Significance

The study presents a method to calibrate and evaluate subject-specific finite element brain models using a combination of advanced magnetic resonance imaging (MRI) data. The imaging data is acquired in human volunteers and includes anatomical MRI, magnetic resonance elastography (MRE), and tagged MRI to generate subject-specific geometry, calibrate subject-specific material properties, and evaluate simulation response using subject-specific brain deformation. This dataset of MRE and tagged MRI allows for a unique evaluation of whether material properties from MRE can be used to create biofidelic computational models of the human brain. The study develops a calibration procedure to readily calculate linear viscoelastic material parameters from MRE data and then provides a sensitivity study of the effect of mechanical heterogeneity of the brain on simulation response. The calibrated computational models are used to simulate each subject's tagged MRI experiment; the results show good agreement between the simulated and experimental strain fields. The presented study and results will be informative in guiding the calibration of subject-specific computational brain model from experimental MRE data. The processed MRI, MRE, and tagged MRI data are publicly available at https://www.nitrc.org/projects/bbir/.

Abstract Image

Abstract Image

Abstract Image

将磁共振弹性成像的材料特性整合到特定主题的人脑计算模型中
脑成像和计算方法的进步促进了特定学科计算脑模型的创建,帮助研究人员通过模拟冲击来研究脑创伤。磁共振弹性成像(MRE)作为一种非侵入性机械神经成像工具的出现,使得在低应变、谐波载荷下对材料特性的体内估计成为可能。该领域的一个悬而未决的问题是如何将这些数据集成到计算模型中。本研究的目的是使用在人类志愿者中获得的新的MRI数据集来生成具有受试者特定解剖结构和材料特性的模型,然后将模拟的大脑变形与非损伤载荷下的受试者特定大脑变形数据进行比较。用直接从MRE数据估计的线性粘弹性(LVE)材料特性对5个对象的模型进行了模拟。将模型预测与使用标记MRI在同一受试者中获得的实验脑变形进行比较。模型结果与实测峰值应变分量的空间分布和大小相吻合,且第95百分位平面内峰值应变在0.005 mm/mm范围内,最大主应变在0.012 mm/mm范围内。对材料异质性的敏感性也进行了研究。具有均匀脑特性的模型和具有多达十个区域的脑特性的模型模拟的脑变形非常相似(峰值应变的平均绝对差小于0.0015 mm/mm)。将材料特性直接从MRE中纳入生物领域特定模型是未来研究高阶模型特征和在更严重载荷条件下进行模拟的重要一步。该研究提出了一种结合先进的磁共振成像(MRI)数据校准和评估受试者特定的有限元脑模型的方法。成像数据是在人类志愿者中获得的,包括解剖MRI、磁共振弹性成像(MRE)和标记MRI,以生成受试者特定的几何形状,校准受试者特定的材料特性,并使用受试者特定的大脑变形来评估模拟反应。MRE和标记MRI的数据集允许对MRE的材料特性是否可用于创建人类大脑的生物模拟计算模型进行独特的评估。该研究开发了一种校准程序,可以从MRE数据中轻松计算线性粘弹性材料参数,然后提供了大脑机械异质性对模拟反应影响的灵敏度研究。校正后的计算模型用于模拟每个受试者的标记MRI实验;结果表明,模拟应变场与实验应变场吻合较好。本文的研究和结果将指导基于实验MRE数据的特定受试者计算脑模型的校准。经过处理的MRI、MRE和标记的MRI数据可在https://www.nitrc.org/projects/bbir/上公开获取。
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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来源期刊
Brain multiphysics
Brain multiphysics Physics and Astronomy (General), Modelling and Simulation, Neuroscience (General), Biomedical Engineering
CiteScore
4.80
自引率
0.00%
发文量
0
审稿时长
68 days
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