The White Matter Fiber Tract Deforms Most in the Perpendicular Direction During In Vivo Volunteer Impacts.

IF 3.9 2区 医学 Q1 CLINICAL NEUROLOGY
Zhou Zhou, Christoffer Olsson, T Christian Gasser, Xiaogai Li, Svein Kleiven
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Abstract

White matter (WM) tract-related strains are increasingly used to quantify brain mechanical responses, but their dynamics in live human brains during in vivo impact conditions remain largely unknown. Existing research primarily looked into the normal strain along the WM fiber tracts (i.e., tract-oriented normal strain), but it is rarely the case that the fiber tract only endures tract-oriented normal strain during impacts. In this study, we aim to extend the in vivo measurement of WM fiber deformation by quantifying the normal strain perpendicular to the fiber tract (i.e., tract-perpendicular normal strain) and the shear strain along and perpendicular to the fiber tract (i.e., tract-oriented shear strain and tract-perpendicular shear strain, respectively). To achieve this, we combine the three-dimensional strain tensor from the tagged magnetic resonance imaging with the diffusion tensor imaging (DTI) from an open-access dataset, including 44 volunteer impacts under two head loading modes, i.e., neck rotations (N = 30) and neck extensions (N = 14). The strain tensor is rotated to the coordinate system with one axis aligned with DTI-revealed fiber orientation, and then four tract-related strain measures are calculated. The results show that tract-perpendicular normal strain peaks are the largest among the four strain types (p < 0.05, Friedman's test). The distribution of tract-related strains is affected by the head loading mode, of which laterally symmetric patterns with respect to the midsagittal plane are noted under neck extensions, but not under neck rotations. Our study presents a comprehensive in vivo strain quantification toward a multifaceted understanding of WM dynamics. We find that the WM fiber tract deforms most in the perpendicular direction, illuminating new fundamentals of brain mechanics. The reported strain images can be used to evaluate the fidelity of computational head models, especially those intended to predict fiber deformation under noninjurious conditions.

白质纤维束在体内志愿者撞击过程中垂直方向的变形最大。
白质(WM)纤维束相关应变越来越多地被用于量化大脑的机械反应,但它们在活体撞击条件下的动态变化在很大程度上仍不为人所知。现有研究主要研究沿白质纤维束的正常应变(即面向纤维束的正常应变),但在撞击过程中纤维束仅承受面向纤维束的正常应变的情况很少见。在本研究中,我们旨在通过量化垂直于纤维束的法向应变(即纤维束垂直法向应变)以及沿纤维束和垂直于纤维束的剪切应变(即纤维束导向剪切应变和纤维束垂直剪切应变)来扩展体内 WM 纤维变形的测量。为此,我们将标记磁共振成像的三维应变张量与弥散张量成像(DTI)相结合,后者来自一个开放获取的数据集,包括 44 名志愿者在两种头部加载模式下受到的撞击,即颈部旋转(30 人)和颈部伸展(14 人)。将应变张量旋转到坐标系,坐标系的一个轴与 DTI 显示的纤维方向对齐,然后计算出四个束相关的应变测量值。结果显示,在四种应变类型中,束垂直正常应变峰值最大(P < 0.05,Friedman 检验)。束相关应变的分布受头部加载模式的影响,其中颈部伸展时相对于中矢状面的横向对称模式明显,而颈部旋转时则不明显。我们的研究提出了一种全面的活体应变量化方法,旨在从多方面了解 WM 的动态变化。我们发现 WM 纤维束在垂直方向上变形最大,这揭示了大脑力学的新基础。所报告的应变图像可用于评估头部计算模型的保真度,尤其是那些旨在预测非损伤条件下纤维变形的模型。
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来源期刊
Journal of neurotrauma
Journal of neurotrauma 医学-临床神经学
CiteScore
9.20
自引率
7.10%
发文量
233
审稿时长
3 months
期刊介绍: Journal of Neurotrauma is the flagship, peer-reviewed publication for reporting on the latest advances in both the clinical and laboratory investigation of traumatic brain and spinal cord injury. The Journal focuses on the basic pathobiology of injury to the central nervous system, while considering preclinical and clinical trials targeted at improving both the early management and long-term care and recovery of traumatically injured patients. This is the essential journal publishing cutting-edge basic and translational research in traumatically injured human and animal studies, with emphasis on neurodegenerative disease research linked to CNS trauma.
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