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高性能梯度对基于血氧水平依赖的静息态功能磁共振成像的回波平面成像的益处。

The benefit of high-performance gradients on echo planar imaging for BOLD-based resting-state functional MRI.

机构信息

Department of Radiology, Mayo Clinic, Rochester, MN 55905, United States of America.

Co-first/equal authorship - these authors contributed equally to this work.

出版信息

Phys Med Biol. 2020 Nov 27;65(23):235024. doi: 10.1088/1361-6560/abb2ec.

DOI:10.1088/1361-6560/abb2ec
PMID:33245051
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7976731/
Abstract

Improved gradient performance in an MRI system reduces distortion in echo planar imaging (EPI), which has been a key imaging method for functional studies. A lightweight, low-cryogen compact 3T MRI scanner (C3T) is capable of achieving 80 mT m gradient amplitude with 700 T m s slew rate, in comparison with a conventional whole-body 3T MRI scanner (WB3T, 50 mT m with 200 T m s). We investigated benefits of the high-performance gradients in a high-spatial-resolution (1.5 mm isotropic) functional MRI study. Reduced echo spacing in the EPI pulse sequence inherently leads to less severe geometric distortion, which provided higher accuracy than with WB3T for registration between EPI and anatomical images. The cortical coverage of C3T datasets was improved by more accurate signal depiction (i.e. less dropout or pile-up). Resting-state functional analysis results showed that greater magnitude and extent in functional connectivity (FC) for the C3T than the WB3T when the selected seed region is susceptible to distortions, while the FC matrix for well-known brain networks showed little difference between the two scanners. This shows that the improved quality in EPI is particularly valuable for studying certain brain regions typically obscured by severe distortion.

摘要

MRI 系统中改进的梯度性能可减少磁共振成像(EPI)中的失真,EPI 一直是功能研究的主要成像方法。与传统的全身 3T MRI 扫描仪(WB3T,梯度幅度 50 mT m,上升速率 200 T m s)相比,一款轻便、低制冷剂、紧凑型 3T MRI 扫描仪(C3T)可实现 80 mT m 的梯度幅度和 700 T m s 的上升速率。我们在高空间分辨率(1.5mm 各向同性)功能磁共振成像研究中研究了高性能梯度的优势。EPI 脉冲序列中的回波间距减小固有地导致更不严重的几何失真,与 WB3T 相比,这为 EPI 和解剖图像之间的配准提供了更高的准确性。C3T 数据集的皮质覆盖范围通过更准确的信号描述(即更少的伪影或堆积)得到改善。静息态功能分析结果表明,在所选种子区域易受失真影响时,C3T 的功能连接(FC)幅度和范围大于 WB3T,而对于两个扫描仪已知的脑网络的 FC 矩阵几乎没有差异。这表明,EPI 质量的提高对于研究通常因严重失真而模糊的某些大脑区域特别有价值。

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