一种用于改进高场磁共振波谱成像的半绝热频谱-空间光谱成像（SASSI）序列。

A semiadiabatic spectral-spatial spectroscopic imaging (SASSI) sequence for improved high-field MR spectroscopic imaging.

作者信息

Feldman Rebecca E, Balchandani Priti

机构信息

Translational and Molecular Imaging Institution, Icahn School of Medicine at Mount Sinai, New York, New York, USA.

出版信息

Magn Reson Med. 2016 Oct;76(4):1071-82. doi: 10.1002/mrm.26025. Epub 2015 Oct 31.

DOI:10.1002/mrm.26025

PMID:26519948

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4980274/

Abstract

PURPOSE

MR spectroscopic imaging (MRSI) benefits from operation at 7T due to increased signal-to-noise ratio (SNR) and spectral separation. The 180° radiofrequency (RF) pulses used in the conventional MRSI sequences are particularly susceptible to the variation in the transmitted RF (B1 ) field and severe chemical shift localization errors at 7T. RF power deposition, as measured by specific absorption rate (SAR), also increases with field strength. Adiabatic 180° RF pulses may mitigate the effects of B1 variation. We designed and implemented a semiadiabatic spectral-spatial spectroscopic imaging (SASSI) pulse sequence to provide more uniform spectral data at 7T with reduced SAR.

METHODS

The adiabatic Shinnar-Le Roux algorithm was used to generate a high bandwidth 180° adiabatic spectral-spatial (SPSP) pulse that captured a spectral range containing the main metabolites of interest. A pair of 180° SPSP pulses was used to refocus the signal excited by a 90° SPSP pulse in order to select a 3D volume of interest in the SASSI sequence.

RESULTS

The SASSI pulse sequence produced spectra with more uniform brain metabolite SNR when compared with the conventional nonadiabatic MRSI sequence.

CONCLUSION

摘要

目的

由于信噪比（SNR）提高和频谱分辨率增加，磁共振波谱成像（MRSI）在7T磁场强度下进行具有优势。传统MRSI序列中使用的180°射频（RF）脉冲特别容易受到发射RF（B1）场变化的影响，并且在7T时会出现严重的化学位移定位误差。通过比吸收率（SAR）测量的RF功率沉积也会随着场强增加而增加。绝热180°RF脉冲可能会减轻B1变化的影响。我们设计并实现了一种半绝热频谱空间波谱成像（SASSI）脉冲序列，以在7T时提供更均匀的频谱数据并降低SAR。

方法

使用绝热的Shinnar-Le Roux算法生成一个高带宽180°绝热频谱空间（SPSP）脉冲，该脉冲捕获包含感兴趣主要代谢物的频谱范围。在SASSI序列中，使用一对180°SPSP脉冲来重聚焦由90°SPSP脉冲激发的信号，以便选择一个三维感兴趣体积。

结果

与传统的非绝热MRSI序列相比，SASSI脉冲序列产生的脑代谢物SNR更均匀。

结论

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