MRI R2* captures inflammation in disconnected brain structures after stroke: a translational study.

IF 11.7 1区医学 Q1 CLINICAL NEUROLOGY

Brain Pub Date : 2025-10-03 DOI:10.1093/brain/awaf082

Ismail Koubiyr, Takayuki Yamamoto, Laurent Petit, Nadège Dubourdieu, Elena Avignone, Elise Cozensa, Chloé Galmiche, Hikaru Fukutomi, Igor Sibon, Vincent Dousset, Michel Thiebaut de Schotten, Aude Panatier, Marion Tible, Thomas Tourdias

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引用次数: 0

Abstract

Ischaemic strokes disrupt brain networks, leading to remote effects in key regions like the thalamus, a critical hub for brain functions. However, non-invasive methods to quantify these remote consequences still need to be explored. This study aimed to demonstrate that MRI-derived R2* changes can capture iron accumulation linked with inflammation secondary to stroke-induced disconnection. To link remote R2* changes to stroke-induced disconnection, we first conducted a secondary analysis of 156 prospectively included stroke patients who underwent MRI at baseline and 1-year follow-up. We mapped fibres disconnected by baseline infarcts to compare the R2* changes over 1 year according to the disconnectivity status in specific thalamic nuclei groups. We also identified the variables associated with elevated R2* at 1 year in a multivariate context through linear regressions. In parallel, to understand the biological underpinning of the remote R2* changes, we set up a translational mouse model through photothrombotic induction of focal cortical infarcts or sham procedures in 110 C57BL/6J mice. We explored the mice through combinations of in vivo MRI at 72 h, 2-, 4- and 8-weeks, histology, qPCR for gene expression, mass spectrometry for iron concentration quantification and additional ex vivo high-resolution diffusion tensor imaging. In stroke patients, we found a significant increase of R2* within severely disconnected medial and lateral thalamic nuclei groups from baseline to 1 year. At the same time, no change occurred if these structures were not disconnected. We also showed that the disconnectivity status at baseline was significantly associated with R2* at follow-up, independently from confounders, establishing a direct and independent relationship between baseline disconnection and the subsequent R2* increase within the associated locations. In mice, we recapitulated the patients' conditions by observing increased R2* in the stroke groups, specifically within the disconnected thalamic nuclei. Such remote and focal R2* changes peaked at 2 weeks, preceding and correlating with longer-term atrophy at 8 weeks. We established that the remote R2* increase was spatially and temporally correlated with a significant increase of chemically determined iron load bound to ferritin within activated microglial cells. This study provides critical evidence that R2* is a sensitive marker of inflammation secondary to network disconnection, potentially informing future neuroprotective strategies targeting remote brain regions after stroke.

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MRI R2*捕获中风后断开的大脑结构中的炎症：一项转化研究。

缺血性中风会破坏大脑网络，导致像丘脑这样的关键区域受到远程影响，丘脑是大脑功能的关键中枢。然而，量化这些远程后果的非侵入性方法仍然需要探索。这项研究旨在证明mri衍生的R2*变化可以捕获与中风引起的连接断开继发炎症相关的铁积累。为了将远程R2*变化与脑卒中引起的脑连接断开联系起来，我们首先对156名前瞻性纳入脑卒中患者进行了二次分析，这些患者在基线和1年随访期间接受了MRI检查。我们绘制了基线梗死断开的纤维，根据特定丘脑核群的断开状态，比较1年内R2*的变化。通过线性回归，我们还确定了与1年多变量背景下R2*升高相关的变量。同时，为了了解远程R2*变化的生物学基础，我们在110只C57BL/6J小鼠中通过光血栓诱导局灶性皮质梗死或假手术建立了翻译小鼠模型。我们通过72h、2周、4周和8周的体内MRI、组织学、基因表达的qPCR、铁浓度定量的质谱分析以及额外的体外高分辨率扩散张量成像来研究小鼠。在脑卒中患者中，我们发现严重断开的内侧和外侧丘脑核组的R2*从基线到1年显著增加。与此同时，如果这些结构没有断开，则不会发生变化。我们还发现，基线断连状态与随访时的R2*显著相关，独立于混杂因素，在相关位置建立了基线断连与随后R2*增加之间的直接独立关系。在小鼠中，我们通过观察中风组中R2*的增加，特别是在断开的丘脑核内，重现了患者的病情。这种远端和局灶R2*变化在2周时达到峰值，在8周时发生长期萎缩。我们发现，远程R2*的增加在空间和时间上与激活的小胶质细胞中与铁蛋白结合的化学测定铁负荷的显著增加相关。这项研究提供了关键证据，表明R2*是继发于网络断开的炎症的敏感标志物，可能为中风后针对远端大脑区域的未来神经保护策略提供信息。

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 医学-临床神经学

CiteScore

20.30

自引率

4.10%

发文量

458

审稿时长

3-6 weeks

期刊介绍： Brain, a journal focused on clinical neurology and translational neuroscience, has been publishing landmark papers since 1878. The journal aims to expand its scope by including studies that shed light on disease mechanisms and conducting innovative clinical trials for brain disorders. With a wide range of topics covered, the Editorial Board represents the international readership and diverse coverage of the journal. Accepted articles are promptly posted online, typically within a few weeks of acceptance. As of 2022, Brain holds an impressive impact factor of 14.5, according to the Journal Citation Reports.