Abstract
PurposeTo interleave global and local higher order shimming for single voxel MRS. Single voxel MR spectroscopy requires optimization of the B0 field homogeneity in the region of the voxel to obtain a narrow linewidth and provide high data quality. However, the optimization of local higher order fields on a localized MRS voxel typically leads to large field offsets outside that volume. This compromises interleaved MR sequence elements that benefit from global field homogeneity such as water suppression, interleaved MRS‐fMRI, and MR motion correction.MethodsA shimming algorithm was developed to optimize the MRS voxel homogeneity and the whole brain homogeneity for interleaved sequence elements, using static higher order shims and dynamic linear terms (HOS‐DLT). Shimming performance was evaluated using 6 brain regions and 10 subjects. Furthermore, the benefits of HOS‐DLT was demonstrated for water suppression, MRS‐fMRI, and motion corrected MRS using fat‐navigators.ResultsThe HOS‐DLT algorithm was shown to improve the whole brain homogeneity compared to an MRS voxel‐based shim, without compromising the MRS voxel homogeneity. Improved water suppression over the brain, reduced image distortions in MRS‐fMRI, and improved quality of motion navigators were demonstrated using the HOS‐DLT method.ConclusionHOS‐DLT shimming allowed for both local and global field homogeneity, providing excellent MR spectroscopy data quality, as well as good field homogeneity for interleaved sequence elements, even without the need for dynamic higher order shimming capabilities.
Highlights
1H-magnetic resonance spectroscopy (MRS) is a powerful tool for the noninvasive detection of biochemical processes in the brain
In order to benefit from the increases in signal-to-noise ratio (SNR) and spectral resolution at higher field, it is essential that the local field homogeneity in the MRS voxel is optimized by the use of higher order shimming.[1]
This can be applied in high field and ultra-high field MR systems equipped with higher order shimming coils, in sequences where both local and global homogeneity is important, but a full dynamic higher order eddy current compensation is not available
Summary
1H-magnetic resonance spectroscopy (MRS) is a powerful tool for the noninvasive detection of biochemical processes in the brain. A poor field homogeneity over the brain compromises global water suppression values and increases the chances of spurious echoes generated outside the voxel.[6] Another example is interleaved MRS and functional MRI (fMRI). At 3T, for example, motion corrected MRS was performed with separate linear shim sets for the navigator and MRS voxel, which were switched dynamically.[11] The gradient coils in modern human MRI systems are designed for rapid switching, as they are shielded, and preemphasis is performed per default This is generally not the case for higher order shim coils, and higher order dynamic shimming is complicated by severe eddy currents that are induced by switching the shim currents. The use of HOS-DLT in MRS with prospective motion correction using fat-navigators is shown, enabling the use of HOS for ultra-high field motion correction
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