体素智融合 3T 和 7T 扩散 MRI 数据,提取更准确的纤维方向

IF 2.3 3区 医学 Q3 CLINICAL NEUROLOGY
Zhanxiong Wu, Xinmeng Weng, Jian Shen, Ming Hong
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引用次数: 0

摘要

虽然 7T 扩散磁共振成像(dMRI)具有较高的空间分辨率,但其扩散成像质量通常会受到 B1 不均匀性、T2 衰减、易感性和化学位移造成的信号损失的影响。相比之下,3T dMRI 的扩散角分辨率相对较高,但空间分辨率较低。因此,结合使用 3T 和 7T dMRI 可以提供更详细、更准确的体素纤维方向信息,从而更好地了解大脑结构的连接性。然而,到目前为止,这一课题尚未得到深入探讨。在本研究中,我们探索了融合 3T 和 7T dMRI 数据以提取更高空间分辨率的体素定量参数的可行性。在分别对 3T 和 7T dMRI 数据进行预处理后,将 3T dMRI 容积核心注册到 7T dMRI 空间。然后,将 7T dMRI 数据与核心注册的 3T dMRI B0(b = 0)图像进行协调。最后,根据本研究提出的四种融合规则,将协调后的 7T dMRI 数据与 3T dMRI 数据进行融合。我们采用了来自人类连接组计划的高质量 3T 和 7T dMRI 数据集(N = 24)来测试我们的算法。我们对从 3T-7T 融合 dMRI 容量中估算出的扩散张量(DTs)和方向分布函数(ODFs)进行了统计分析。与 7T dMRI 数据集相比,从融合 dMRI 数据中发现了更多包含多种纤维群的体素。此外,在大津定量各向异性阈值下,从融合 dMRI 数据中提取出了颞脑区域的额外纤维方向,但从 7T dMRI 数据集中却无法提取。这项研究提供了一种新的算法来融合受试者内部的 3T 和 7T dMRI 数据,以提取更详细的体素定量参数信息,为构建更精确的脑结构网络提供了新的视角。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Voxel-Wise Fusion of 3T and 7T Diffusion MRI Data to Extract more Accurate Fiber Orientations

While 7T diffusion magnetic resonance imaging (dMRI) has high spatial resolution, its diffusion imaging quality is usually affected by signal loss due to B1 inhomogeneity, T2 decay, susceptibility, and chemical shift. In contrast, 3T dMRI has relative higher diffusion angular resolution, but lower spatial resolution. Combination of 3T and 7T dMRI, thus, may provide more detailed and accurate information about the voxel-wise fiber orientations to better understand the structural brain connectivity. However, this topic has not yet been thoroughly explored until now. In this study, we explored the feasibility of fusing 3T and 7T dMRI data to extract voxel-wise quantitative parameters at higher spatial resolution. After 3T and 7T dMRI data was preprocessed, respectively, 3T dMRI volumes were coregistered into 7T dMRI space. Then, 7T dMRI data was harmonized to the coregistered 3T dMRI B0 (b = 0) images. Last, harmonized 7T dMRI data was fused with 3T dMRI data according to four fusion rules proposed in this study. We employed high-quality 3T and 7T dMRI datasets (N = 24) from the Human Connectome Project to test our algorithms. The diffusion tensors (DTs) and orientation distribution functions (ODFs) estimated from the 3T-7T fused dMRI volumes were statistically analyzed. More voxels containing multiple fiber populations were found from the fused dMRI data than from 7T dMRI data set. Moreover, extra fiber directions were extracted in temporal brain regions from the fused dMRI data at Otsu’s thresholds of quantitative anisotropy, but could not be extracted from 7T dMRI dataset. This study provides novel algorithms to fuse intra-subject 3T and 7T dMRI data for extracting more detailed information of voxel-wise quantitative parameters, and a new perspective to build more accurate structural brain networks.

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来源期刊
Brain Topography
Brain Topography 医学-临床神经学
CiteScore
4.70
自引率
7.40%
发文量
41
审稿时长
3 months
期刊介绍: Brain Topography publishes clinical and basic research on cognitive neuroscience and functional neurophysiology using the full range of imaging techniques including EEG, MEG, fMRI, TMS, diffusion imaging, spectroscopy, intracranial recordings, lesion studies, and related methods. Submissions combining multiple techniques are particularly encouraged, as well as reports of new and innovative methodologies.
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