Mapping Activity and Functional Organisation of the Motor and Visual Pathways Using ADC-fMRI in the Human Brain

IF 3.5 2区医学 Q1 NEUROIMAGING

Human Brain Mapping Pub Date : 2025-01-21 DOI:10.1002/hbm.70110

Jasmine Nguyen-Duc, Ines de Riedmatten, Arthur P. C. Spencer, Jean-Baptiste Perot, Wiktor Olszowy, Ileana Jelescu

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Abstract

In contrast to blood-oxygenation level-dependent (BOLD) functional MRI (fMRI), which relies on changes in blood flow and oxygenation levels to infer brain activity, diffusion fMRI (DfMRI) investigates brain dynamics by monitoring alterations in the apparent diffusion coefficient (ADC) of water. These ADC changes may arise from fluctuations in neuronal morphology, providing a distinctive perspective on neural activity. The potential of ADC as an fMRI contrast (ADC-fMRI) lies in its capacity to reveal neural activity independently of neurovascular coupling, thus yielding complementary insights into brain function.

To demonstrate the specificity and value of ADC-fMRI, both ADC- and BOLD-fMRI data were collected at 3 T in human subjects during visual stimulation and motor tasks. The first aim of this study was to identify an acquisition design for ADC that minimises BOLD contributions. By examining the timings in responses, we report that ADC 0/1 timeseries (acquired with b values of 0 and 1 ms/ ${μm}^{2}$ ) exhibit residual vascular contamination, while ADC 0.2/1 timeseries (with b values of 0.2 and 1 ms/ ${μm}^{2}$ ) show minimal BOLD influence and higher sensitivity to neuromorphological coupling. Second, a general linear model was employed to identify activation clusters for ADC 0.2/1 and BOLD, from which the average ADC and BOLD responses were calculated. The negative ADC response exhibited a significantly reduced delay relative to the task onset and offset as compared to BOLD. This early onset further supports the notion that ADC is sensitive to neuromorphological rather than neurovascular coupling. Remarkably, in the group-level analysis, positive BOLD activation clusters were detected in the visual and motor cortices, while the negative ADC clusters mainly highlighted pathways in white matter connected to the motor cortex. In the averaged individual level analysis, negative ADC activation clusters were also present in the visual cortex. This finding confirmed the reliability of negative ADC as an indicator of brain function, even in regions with lower vascularisation such as white matter. Finally, we established that ADC-fMRI time courses yield the expected functional organisation of the visual system, including both grey and white matter regions of interest. Functional connectivity matrices were used to perform hierarchical clustering of brain regions, where ADC-fMRI successfully reproduced the expected structure of the dorsal and ventral visual pathways. This organisation was not replicated with the b = 0.2 ms/ ${μm}^{2}$ diffusion-weighted time courses, which can be seen as a proxy for BOLD (via T₂-weighting). These findings underscore the robustness of ADC time courses in functional MRI studies, offering complementary insights into BOLD-fMRI regarding brain function and connectivity patterns.

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使用ADC-fMRI在人脑中绘制运动和视觉通路的活动和功能组织。

与依赖血氧水平（BOLD）的功能MRI （fMRI）不同，fMRI依靠血流和氧合水平的变化来推断大脑活动，而弥散性功能MRI （DfMRI）通过监测水的表观扩散系数（ADC）的变化来研究大脑动力学。这些ADC变化可能是由神经元形态的波动引起的，为神经活动提供了独特的视角。ADC作为功能磁共振成像对比（ADC-fMRI）的潜力在于它能够独立于神经血管耦合显示神经活动，从而对脑功能产生互补的见解。为了证明ADC- fmri的特异性和价值，我们在3 T时收集了人类受试者在视觉刺激和运动任务期间的ADC-和BOLD-fMRI数据。本研究的第一个目的是确定ADC的采集设计，以最大限度地减少BOLD的贡献。通过检测响应的时序，我们报告了ADC 0/1时间序列（b值为0和1 ms/ μ 2 $$ {\upmu \mathrm{m}}^2 $$）显示出残留的血管污染，而ADC 0.2/1时间序列（b值为0.2和1 ms/ μ 2 $$ {\upmu \mathrm{m}}^2 $$）显示最小的BOLD影响和对神经形态耦合的更高灵敏度。其次，采用一般线性模型识别ADC 0.2/1和BOLD的激活簇，并以此计算ADC和BOLD的平均响应。与BOLD相比，负ADC反应相对于任务开始和偏移表现出显著减少的延迟。这种早期发病进一步支持了ADC对神经形态而非神经血管耦合敏感的观点。值得注意的是，在组水平分析中，在视觉和运动皮质中检测到阳性的BOLD激活簇，而ADC阴性簇主要突出与运动皮质相连的白质通路。在平均个体水平分析中，在视觉皮层中也存在负ADC激活簇。这一发现证实了ADC阴性作为脑功能指标的可靠性，即使在血管化较低的区域（如白质）也是如此。最后，我们确定ADC-fMRI时间过程产生视觉系统的预期功能组织，包括感兴趣的灰质和白质区域。功能连接矩阵用于对大脑区域进行分层聚类，其中ADC-fMRI成功地再现了背侧和腹侧视觉通路的预期结构。b = 0.2 ms/ μm 2 $$ {\upmu \mathrm{m}}^2 $$扩散加权时间过程不能复制这种组织，扩散加权时间过程可以被视为BOLD的代理（通过t2加权）。这些发现强调了ADC时间过程在功能性MRI研究中的稳健性，为BOLD-fMRI在脑功能和连接模式方面提供了补充见解。

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来源期刊

Human Brain Mapping 医学-核医学

CiteScore

8.30

自引率

6.20%

发文量

401

审稿时长

3-6 weeks

期刊介绍： Human Brain Mapping publishes peer-reviewed basic, clinical, technical, and theoretical research in the interdisciplinary and rapidly expanding field of human brain mapping. The journal features research derived from non-invasive brain imaging modalities used to explore the spatial and temporal organization of the neural systems supporting human behavior. Imaging modalities of interest include positron emission tomography, event-related potentials, electro-and magnetoencephalography, magnetic resonance imaging, and single-photon emission tomography. Brain mapping research in both normal and clinical populations is encouraged. Article formats include Research Articles, Review Articles, Clinical Case Studies, and Technique, as well as Technological Developments, Theoretical Articles, and Synthetic Reviews. Technical advances, such as novel brain imaging methods, analyses for detecting or localizing neural activity, synergistic uses of multiple imaging modalities, and strategies for the design of behavioral paradigms and neural-systems modeling are of particular interest. The journal endorses the propagation of methodological standards and encourages database development in the field of human brain mapping.