通过布洛克-西格尔位移和梯度选择性激发。

Selective excitation localized by the Bloch-Siegert shift and a gradient.

机构信息

Institute of Imaging Science, Vanderbilt University, Nashville, Tennessee, USA.

Department of Biomedical Engineering, Vanderbilt University, Nashville, Tennessee, USA.

出版信息

Magn Reson Med. 2022 Sep;88(3):1081-1097. doi: 10.1002/mrm.29271. Epub 2022 Apr 25.

DOI:10.1002/mrm.29271

PMID:35468232

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9246893/

Abstract

PURPOSE

To perform -selective excitation using the Bloch-Siegert shift for spatial localization.

THEORY AND METHODS

A -selective excitation is produced by an radiofrequency (RF) pulse consisting of two summed component pulses: an off-resonant pulse that induces a -dependent Bloch-Siegert frequency shift and a frequency-selective excitation pulse. The passband of the pulse can be tailored by adjusting the frequency content of the frequency-selective pulse, as in conventional gradient-localized excitation. Fine magnetization profile control is achieved by using the Shinnar-Le Roux algorithm to design the frequency-selective excitation pulse. Simulations analyzed the pulses' robustness to off-resonance, their suitability for multi-echo spin echo pulse sequences, and how their performance compares to that of rotating-frame selective excitation pulses. The pulses were evaluated experimentally on a 47.5 mT MRI scanner using an RF gradient transmit coil. Multiphoton resonances produced by the pulses were characterized and their distribution across predicted.

RESULTS

With correction for varying across the desired profile, the proposed pulses produced selective excitation with the specified profile characteristics. The pulses were robust against off-resonance and RF amplifier distortion, and suitable for multi-echo pulse sequences. Experimental profiles closely matched simulated patterns.

CONCLUSION

The Bloch-Siegert shift can be used to perform -gradient-free selective excitation, enabling the excitation of slices or slabs in RF gradient-encoded MRI.

摘要

目的

利用 Bloch-Siegert 频移进行 - 选择性激发以实现空间定位。

理论与方法

通过由两个叠加分量脉冲组成的射频（RF）脉冲产生 - 选择性激发：一个离共振脉冲，它会引起 - 依赖性 Bloch-Siegert 频移和频率选择性激发脉冲。通过调整频率选择性脉冲的频率内容，可以调整脉冲的通带，就像在传统的梯度定位激发中一样。通过使用 Shinnar-Le Roux 算法来设计频率选择性激发脉冲，可以实现精细的磁化分布控制。模拟分析了脉冲对离共振的鲁棒性、它们在多回波自旋回波脉冲序列中的适用性以及它们与旋转框架选择性激发脉冲的性能比较。在一台 47.5 mT 的 MRI 扫描仪上使用 RF 梯度发射线圈对这些脉冲进行了实验评估。对由这些脉冲产生的多光子共振进行了表征，并预测了它们在整个区域的分布。

结果

对所需轮廓内的变化进行校正后，所提出的脉冲产生了具有指定轮廓特征的选择性激发。这些脉冲对离共振和 RF 放大器失真具有鲁棒性，并且适用于多回波脉冲序列。实验轮廓与模拟图案非常匹配。

结论

Bloch-Siegert 频移可用于执行无 - 梯度选择性激发，从而能够在 RF 梯度编码 MRI 中激发切片或板层。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4d2a/9246893/3bf81f25531c/nihms-1794739-f0001.jpg

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