Characterization of material properties and deformation in the ANGUS phantom during mild head impacts using MRI.

A. Knutsen, S. Vidhate, Grace McIlvain, J. Luster, Eric J. Galindo, Curtis L. Johnson, D. Pham, J. Butman, R. Mejía-Alvarez, M. Tartis, A. Willis
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引用次数: 1

Abstract

Traumatic brain injury (TBI) is a major health concern affecting both military and civilian populations. Despite notable advances in TBI research in recent years, there remains a significant gap in linking the impulsive loadings from a blast or a blunt impact to the clinical injury patterns observed in TBI. Synthetic head models or phantoms can be used to establish this link as they can be constructed with geometry, anatomy, and material properties that match the human brain, and can be used as an alternative to animal models. This study presents one such phantom called the Anthropomorphic Neurologic Gyrencephalic Unified Standard (ANGUS) phantom, which is an idealized gyrencephalic brain phantom composed of polyacrylamide gel. Here we mechanically characterized the ANGUS phantom using tagged magnetic resonance imaging (MRI) and magnetic resonance elastography (MRE), and then compared the outcomes to data obtained in healthy volunteers. The direct comparison between the phantom's response and the data from a cohort of in vivo human subjects demonstrate that the ANGUS phantom may be an appropriate model for bulk tissue response and gyral dynamics of the human brain under small amplitude linear impulses. However, the phantom's response differs from that of the in vivo human brain under rotational impacts, suggesting avenues for future improvements to the phantom.
在轻度头部撞击过程中使用MRI表征ANGUS假体的材料特性和变形。
创伤性脑损伤(TBI)是影响军人和平民人口的主要健康问题。尽管近年来TBI研究取得了显著进展,但在将爆炸或钝器撞击产生的脉冲负荷与TBI中观察到的临床损伤模式联系起来方面仍存在重大差距。合成头部模型或模型可以用来建立这种联系,因为它们可以用与人脑相匹配的几何、解剖和材料属性来构建,并且可以用作动物模型的替代品。本研究提出了一种拟人化神经回头统一标准(ANGUS)幻像,它是一种由聚丙烯酰胺凝胶组成的理想化的回头脑幻像。在这里,我们使用标记磁共振成像(MRI)和磁共振弹性成像(MRE)对ANGUS幻体进行机械表征,然后将结果与健康志愿者的数据进行比较。通过与人体实验数据的直接比较表明,ANGUS模型可以作为小幅度线性脉冲作用下的人体组织反应和脑回动力学的合适模型。然而,在旋转冲击下,幻肢的反应与体内人脑的反应不同,这为未来对幻肢的改进提供了途径。
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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