7T 磁共振弥散成像的进展:神经成像技术创新与应用

iRadiology Pub Date : 2024-07-17 DOI:10.1002/ird3.92
Lisha Nie, Siyi Li, Bing Wu, Yuhui Xiong, Jeffrey McGovern, Yunling Wang, Huilou Liang
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引用次数: 0

摘要

7特斯拉(7T)磁共振成像系统的开发为探索较高场强下扩散成像的优势开辟了新途径,尤其是在神经科学研究中。本综述通过探讨以下问题,研究 7T 扩散成像是否比较低场强有明显优势:技术挑战和相应策略:挑战包括实现更短的横向弛豫/有效横向弛豫时间以及更大的 B0 和 B1 不均匀性。包括高性能梯度系统、并行成像、多镜头采集和并行传输在内的先进技术可以缓解这些问题。3-Tesla 和 7T 扩散成像的比较:多路复用灵敏度编码和深度学习重建(DLR)等技术已被开发出来,以减少伪影并提高图像质量。这项对比分析表明,在 7T 下,利用强大的梯度系统,信噪比和空间分辨率都有了显著提高,从而促进了微观结构变化的可视化。尽管在 7T 下存在更大的几何失真和信号不均匀性,但该系统在高 b 值成像和高分辨率弥散张量成像方面显示出明显的优势。此外,多路复用灵敏度编码大大减少了图像模糊和失真,而 DLR 则大大提高了信噪比和图像清晰度。结构分析和疾病特征描述中的 7T 扩散应用:这篇综述讨论了 7T 扩散成像在结构分析和疾病特征描述中的潜在应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Advancements in 7T magnetic resonance diffusion imaging: Technological innovations and applications in neuroimaging

Advancements in 7T magnetic resonance diffusion imaging: Technological innovations and applications in neuroimaging

The development of 7-Tesla (7T) magnetic resonance imaging systems has opened new avenues for exploring the advantages of diffusion imaging at higher field strengths, especially in neuroscience research. This review investigates whether 7T diffusion imaging offers significant benefits over lower field strengths by addressing the following: Technical challenges and corresponding strategies: Challenges include achieving shorter transverse relaxation/effective transverse relaxation times and greater B0 and B1 inhomogeneities. Advanced techniques including high-performance gradient systems, parallel imaging, multi-shot acquisition, and parallel transmission can mitigate these issues. Comparison of 3-Tesla and 7T diffusion imaging: Technologies such as multiplexed sensitivity encoding and deep learning reconstruction (DLR) have been developed to mitigate artifacts and improve image quality. This comparative analysis demonstrates significant improvements in the signal-to-noise ratio and spatial resolution at 7T with a powerful gradient system, facilitating enhanced visualization of microstructural changes. Despite greater geometric distortions and signal inhomogeneity at 7T, the system shows clear advantages in high b-value imaging and high-resolution diffusion tensor imaging. Additionally, multiplexed sensitivity encoding significantly reduces image blurring and distortion, and DLR substantially improves the signal-to-noise ratio and image sharpness. 7T diffusion applications in structural analysis and disease characterization: This review discusses the potential applications of 7T diffusion imaging in structural analysis and disease characterization.

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