功能磁共振成像的快速发展体现在速度、分辨率和精度上。

The rapid development of high speed, resolution and precision in fMRI.

机构信息

University of California, Berkeley and Advanced MRI Technologies, Berkeley, CA, USA.

出版信息

Neuroimage. 2012 Aug 15;62(2):720-5. doi: 10.1016/j.neuroimage.2012.01.049. Epub 2012 Jan 14.

DOI:10.1016/j.neuroimage.2012.01.049

PMID:22281677

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3389295/

Abstract

MRI pulse sequences designed to increase the speed and spatial resolution of fMRI have always been a hot topic. Here, we review and chronicle the history behind some of the pulse sequence ideas that have contributed not only to the enhancement of fMRI acquisition but also to diffusion imaging. (i) Partial Fourier EPI allows lengthening echo trains for higher spatial resolution while maintaining optimal TE and BOLD sensitivity. (ii) Inner-volume EPI renamed zoomed-EPI, achieves extremely high spatial resolution and has been applied to fMRI at 7Tesla to resolve cortical layer activity and columnar level fMRI. (iii) An early non-BOLD approach while unsuccessful for fMRI created a diffusion sequence of bipolar pulses called 'twice refocused spin echo' now widely used for high-resolution DTI and HARDI neuronal fiber track imaging. (iv) Multiplexed EPI shortens TR to a few hundred milliseconds, increasing sampling rates and statistical power in fMRI.

摘要

旨在提高 fMRI 速度和空间分辨率的 MRI 脉冲序列一直是一个热门话题。在这里，我们回顾和记录了一些脉冲序列思想的历史，这些思想不仅有助于增强 fMRI 采集，而且有助于扩散成像。(i) 部分傅里叶 EPI 允许延长回波链以提高空间分辨率，同时保持最佳 TE 和 BOLD 灵敏度。(ii) 内体积 EPI 重新命名为变焦 EPI，实现了极高的空间分辨率，并已应用于 7T 磁共振成像以解析皮质层活动和柱状 fMRI。(iii) 一种早期的非 BOLD 方法虽然对 fMRI 不成功，但创建了一种称为“双重聚焦自旋回波”的双极脉冲扩散序列，现在广泛用于高分辨率 DTI 和 HARDI 神经元纤维跟踪成像。(iv) 多路复用 EPI 将 TR 缩短到几百毫秒，增加 fMRI 中的采样率和统计能力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d0dc/3389295/cd453981bd5f/nihms350406f1a.jpg

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A k-space analysis of small-tip-angle excitation. 1989.小角度激发的k空间分析。1989年。

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