Dynamic shimming in the cervical spinal cord for multi-echo gradient-echo imaging at 3 T

Q4 Neuroscience Neuroimage. Reports Pub Date : 2023-03-01 DOI:10.1016/j.ynirp.2022.100150
E. Alonso-Ortiz , D. Papp , A. D'Astous , J. Cohen-Adad
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引用次数: 2

Abstract

Obtaining high quality images of the spinal cord with MRI is difficult, partly due to the fact that the spinal cord is surrounded by a number of structures that have differing magnetic susceptibility. This causes inhomogeneities in the magnetic field, which in turn lead to image artifacts. In order to address this issue, linear compensation gradients can be employed. The latter can be generated using an MRI scanner's first order gradient coils and adjusted on a per-slice basis, in order to correct for through-plane (“z”) magnetic field gradients. This approach is referred to as z-shimming. The aim of this study is two-fold. The first aim was to replicate aspects of a previous study wherein z-shimming was found to improve image quality in T2*-weighted echo-planar imaging. Our second aim was to improve upon the z-shimming approach by including in-plane compensation gradients and adjusting the compensation gradients during the image acquisition process so that they take into account respiration-induced magnetic field variations. We refer to this novel approach as realtime dynamic shimming. Measurements performed in a group of 12 healthy volunteers at 3 T show improved signal homogeneity along the spinal cord when using z-shimming. Signal homogeneity may be further improved by including realtime compensation for respiration-induced field gradients and by also doing this for gradients along the in-plane axes.

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颈脊髓动态摆振用于3T多回波梯度回波成像
用MRI获得高质量的脊髓图像是困难的,部分原因是脊髓被许多具有不同磁化率的结构包围。这会导致磁场的不均匀性,进而导致图像伪影。为了解决这个问题,可以采用线性补偿梯度。后者可以使用MRI扫描仪的一阶梯度线圈生成,并在每个切片的基础上进行调整,以校正穿过平面(“z”)的磁场梯度。这种方法被称为z匀场。这项研究的目的有两个。第一个目的是复制先前研究的各个方面,其中发现z匀场可以提高T2*加权回波平面成像的图像质量。我们的第二个目标是通过包括平面内补偿梯度并在图像采集过程中调整补偿梯度来改进z匀场方法,从而将呼吸引起的磁场变化考虑在内。我们将这种新颖的方法称为实时动态匀场。在一组12名健康志愿者中进行的3T测量显示,当使用z摆振时,沿脊髓的信号均匀性得到改善。通过包括对呼吸引起的场梯度的实时补偿以及通过对沿平面内轴的梯度也这样做,可以进一步改善信号的均匀性。
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来源期刊
Neuroimage. Reports
Neuroimage. Reports Neuroscience (General)
CiteScore
1.90
自引率
0.00%
发文量
0
审稿时长
87 days
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