MR elastography-based detection of impaired skull-brain mechanical decoupling performance in response to repetitive head impacts.

IF 4.7 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

European Radiology Pub Date : 2025-06-01 Epub Date: 2024-12-10 DOI:10.1007/s00330-024-11265-7

Xiang Shan, Matthew C Murphy, Yi Sui, Keni Zheng, Emi Hojo, Armando Manduca, Richard L Ehman, John Huston, Ziying Yin

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引用次数: 0

Abstract

Objective: To evaluate MR elastography (MRE)-assessed biomarkers for detecting changes in skull-brain mechanical decoupling performance induced by repetitive head impacts (RHIs).

Methods: This prospective single-center study enrolled 80 asymptomatic participants (2017-2023) divided into three groups: no exposure (RHI(-)), low-impact (low RHI(+)), and high-impact (high RHI(+)). Four MRE-based parameters were evaluated to analyze the skull-brain decoupling performance: brain-to-skull rotational transmission ratio (Rtr), cortical shear strain (normalized OSS (octahedral shear strain)), cortical volumetric strain (normalized ONS (octahedral normal strain)), and the OSS-to-ONS ratio. Confounding factors (age/skull-brain distance, sex) were controlled with a linear regression model. One-way ANOVA with Tukey's post-hoc test was used for group comparisons.

Results: The high RHI(+) showed a significantly increased adjusted Rtr compared to the RHI(-) and low RHI(+) (p < 0.001). Higher adjusted OSS-to-ONS ratios were found in the high RHI(+) in the frontal (q < 0.05), parietal (q < 0.001), and occipital (q < 0.05) lobes compared to the RHI(-), and in all regions compared to the low RHI(+) (q < 0.05). The high RHI(+) exhibited lower adjusted normalized ONS and OSS in the temporal lobe (q < 0.05) compared to the low RHI(+). These findings suggest that recent and prolonged RHI exposures may impair the skull-brain decoupling performance, affecting the capacity of the interface to isolate the brain by dampening skull-to-brain motion transmission and modulating brain surface deformation.

Conclusion: This study reveals evidence of impaired decoupling function at the skull-brain interface resulting from RHI exposure and demonstrates MRE-based biomarkers for early detection of this impairment.

Key points: Question The skull-brain interface is crucial for brain protection under impact, but its early mechanical responses to repetitive head impacts (RHIs) remain largely unknown. Findings Mechanical changes (more rotation and a shift in shear relative to volumetric strain) across the skull-brain interface were observed in participants under high RHI exposure. Clinical relevance Our study developed MR elastography (MRE)-based measurements to detect changes in the skull-brain interface caused by RHI, suggesting that MRE holds promise for noninvasively quantifying cumulative injury and potential future clinical interventions for individuals with high RHI exposure.

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基于磁共振弹性成像技术检测重复性头部撞击时受损的颅脑机械解耦性能。

目的：评价磁共振弹性成像（MRE）评估的生物标志物在检测重复性头部撞击（RHIs）引起的颅脑机械解耦性能变化方面的作用。方法：本前瞻性单中心研究纳入了80名无症状参与者（2017-2023），分为三组：无接触（RHI(-)）、低影响（低RHI(+)）和高影响（高RHI(+)）。评估4个基于mre的参数来分析颅脑解耦性能：脑-颅骨旋转传动比（Rtr）、皮质剪切应变（归一化OSS（八面体剪切应变））、皮质体积应变（归一化ONS（八面体正应变））和OSS- ONS比。用线性回归模型控制混杂因素（年龄/颅脑距离、性别）。组间比较采用单因素方差分析和Tukey事后检验。结果：与RHI（-）和低RHI（+）相比，高RHI（+）显示出显著增加的调整Rtr (p)。结论：本研究揭示了RHI暴露导致颅骨-脑界面解耦功能受损的证据，并证明了基于核磁共振的生物标志物可用于早期检测这种损伤。颅骨-脑界面对脑在撞击下的保护至关重要，但其对重复性头部撞击（RHIs）的早期机械反应在很大程度上仍然未知。在高RHI暴露的参与者中，观察到颅骨-脑界面的机械变化（更多的旋转和相对于体积应变的剪切变化）。我们的研究开发了基于MR弹性成像（MRE）的测量方法来检测由RHI引起的颅脑界面变化，这表明MRE有望无创性地量化累积损伤，并为高RHI暴露个体提供潜在的未来临床干预措施。

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

European Radiology 医学-核医学

CiteScore

11.60

自引率

8.50%

发文量

874

审稿时长

2-4 weeks

期刊介绍： European Radiology (ER) continuously updates scientific knowledge in radiology by publication of strong original articles and state-of-the-art reviews written by leading radiologists. A well balanced combination of review articles, original papers, short communications from European radiological congresses and information on society matters makes ER an indispensable source for current information in this field. This is the Journal of the European Society of Radiology, and the official journal of a number of societies. From 2004-2008 supplements to European Radiology were published under its companion, European Radiology Supplements, ISSN 1613-3749.