用于人脑映射的同时扩散和T1加权对比成像

Q3 Health Professions

Iranian Journal of Medical Physics Pub Date : 2020-08-21 DOI:10.22038/IJMP.2020.49358.1795

M. Nezamzadeh, N. Schuff

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引用次数: 0

摘要

引言：扩散张量成像（DTI）通常使用回声平面成像（EPI）进行人脑映射。然而，EPI存在易感性失真，需要精细的图像后处理。此外，单独的DTI在评估大脑的灰质和白质边界方面是有限的，这对于准确成像脑萎缩很重要。本研究的目的是设计和评估用于人脑标测的同时扩散和T1加权高分辨率成像。材料和方法：T1加权的三维磁化制备快速梯度回波（3DMPRAGE）是绘制大脑灰质和白质结构的常用方法，通过模拟和实验将其扩展到结合扩散编码，以开发高分辨率DTI和T1加权的人脑数据。结果：在4特斯拉磁场强度下，使用模拟以及体内人脑研究的实验结果，将DTI对比度（即分数各向异性（FA）和平均扩散率（MD））结合到T1加权的3D MPRAGE中，可以改善灰质和白质亚结构边界之间的对比度。此外，将扩散编码结合到3D MPRAGE中避免了通常在基于EPI的DTI中看到的固有图像失真。结论：本研究表明，DTI加权三维MPRAGE结合T1w用于人脑成像是可行的，有望有助于改善灰质/白质边界的评估。

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Simultaneous Diffusion and T1 Weighted Contrast Imaging for Human Brain Mapping

Introduction: Diffusion tensor imaging (DTI) is conventionally performed using echo planar imaging (EPI) for human brain mapping. However, EPI suffers from susceptibility distortion, requiring elaborate image post processing. Besides, DTI alone is limited in assessing gray and white matter boundaries of the brain, which is important for accurately imaging brain atrophy. The goal of this study was to design and evaluate simultaneous diffusion and T1 weighting high resolution imaging for human brain mapping. Materials and Methods: Three dimensional Magnetization-prepared rapid gradient-echo (3D MPRAGE) with T1 weighting, which is generally the method of choice for mapping gray and white matter structures in the brain, was extended to incorporate diffusion encoding using simulation and experiment to develop high resolution DTI and T1-weighted human brain data. Results: It is shown that the incorporation of DTI contrast (i.e. fractional anisotropy (FA) and mean diffusivity (MD)) into T1 weighted 3D MPRAGE using simulations as well as experimental results from in-vivo human brain studies at 4 Tesla magnetic field strength improves the contrast between gray and white matter sub-structural boundaries. Moreover, incorporating diffusion encoding into 3D MPRAGE avoids the inherent image distortions typically seen in EPI based DTI.Conclusion: This study suggests DTI weighted 3D MPRAGE combined with T1w is feasible for human brain imaging and expected to benefit improved assessment of gray/white matter boundaries.

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来源期刊

Iranian Journal of Medical Physics Health Professions-Radiological and Ultrasound Technology

CiteScore

1.00

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： Iranian Journal of Medical Physics (IJMP) is the official scientific bimonthly publication of the Iranian Association of Medical Physicists. IJMP is an international and multidisciplinary journal, peer review, free of charge publication and open access. This journal devoted to publish Original Papers, Review Articles, Short Communications, Technical Notes, Editorial and Letters to the Editor in the field of “Medical Physics” involving both basic and clinical research. Submissions of manuscript from all countries are welcome and will be reviewed by at least two expert reviewers.