4T 下人类大脑三维回波平面光谱成像（3D EPSI）中局部 B0 位移的校正

Correction of local B0 shifts in 3D EPSI of the human brain at 4 T.

作者信息

Ebel Andreas, Maudsley Andrew A, Schuff Norbert

机构信息

Northern California Institute for Research and Education, DVA Medical Center San Francisco, MR Unit (114M), 4150 Clement St., San Francisco, CA 94121, USA.

出版信息

Magn Reson Imaging. 2007 Apr;25(3):377-80. doi: 10.1016/j.mri.2006.09.004. Epub 2006 Nov 13.

DOI:10.1016/j.mri.2006.09.004

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2040064/

Abstract

High-spatial-resolution acquisition (HR) was previously proposed for 3D echo-planar spectroscopic imaging (EPSI) in combination with a high-spatial-resolution water reference EPSI data set to minimize inhomogeneous spectral line broadening, allowing for local frequency shift (B(0) shift) correction in human brain metabolite maps at 1.5 T (Ebel A et al., Magn. Reson. Imaging 21:113-120, 2003). At a higher magnetic field strength, B(0), increased field inhomogeneities typically lead to increased line broadening. Additionally, increased susceptibility variations render shimming of the main magnetic field over the whole head more difficult. This study addressed the question whether local B(0)-shift correction still helps limit line broadening in whole-brain 3D EPSI at higher magnetic fields. The combination of HR and local B(0)-shift correction to limit line broadening was evaluated at 4 T. Similar to the results at 1.5 T, the approach provided a high yield of voxels with good spectral quality for 3D EPSI, resulting in improved brain coverage.

摘要

高空间分辨率采集（HR）先前已被提出用于三维回波平面光谱成像（EPSI），并结合高空间分辨率水参考EPSI数据集，以最小化不均匀谱线展宽，从而在1.5T下对人脑代谢物图谱进行局部频率偏移（B(0)偏移）校正（Ebel A等人，《磁共振成像》21:113 - 120，2003年）。在更高的磁场强度下，B(0)增加，场不均匀性通常会导致谱线展宽增加。此外，易感性变化增加使得在整个头部对主磁场进行匀场更加困难。本研究探讨了在更高磁场下局部B(0)偏移校正是否仍有助于限制全脑三维EPSI中的谱线展宽这一问题。在4T下评估了HR与局部B(0)偏移校正相结合以限制谱线展宽的情况。与1.5T时的结果类似，该方法为三维EPSI提供了大量具有良好光谱质量的体素，从而改善了脑覆盖范围。

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