Analysis of the multi-echo spin-echo pulse sequence

IF 0.4 4区化学 Q4 CHEMISTRY, PHYSICAL

Concepts in Magnetic Resonance Part A Pub Date : 2017-12-04 DOI:10.1002/cmr.a.21402

Yuval Zur

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引用次数: 4

Abstract

The multi-echo spin-echo sequence is a series of operators, referred to as periodic operators. Each periodic operator consists of a free rotation (no RF), a refocusing RF pulse, and another free rotation, identical to the first one. A preparation operator that precedes the periodic operators converts the equilibrium magnetization M_z into an initial magnetization M_i. It is shown that a multi-echo sequence is equivalent to a simple rotation of the magnetization about a tilted axis. The component of M_i along the rotation axis is stationary and provides a stable signal, denoted pseudo steady-state. The perpendicular component rotates and eventually de-phases. Using this model, we derive analytic expressions to the signal for different preparation operators, and show how to align M_i with the rotation axis such that the signal is maximized. A simple and efficient algorithm is presented to calculate the Fourier coefficients of the magnetization during the sequence using the discrete Fourier transform. Finally, formulas of the echo signal when unavoidable phase errors are generated are derived. We show how to eliminate artifacts caused by these errors and restore the original image.

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多回波自旋回波脉冲序列分析

多回波自旋回波序列是一系列算子，称为周期算子。每个周期算子由一个自由旋转(无射频)、一个重聚焦射频脉冲和另一个与第一个相同的自由旋转组成。在周期算符之前的准备算符将平衡磁化强度Mz转换为初始磁化强度Mi。结果表明，多回波序列相当于磁化强度绕倾斜轴的简单旋转。Mi沿旋转轴方向的分量是静止的，提供一个稳定的信号，记作伪稳态。垂直分量旋转并最终消相。利用该模型，我们推导了不同制备算子的信号解析表达式，并展示了如何将Mi与旋转轴对齐以使信号最大化。提出了一种利用离散傅里叶变换计算序列中磁化系数的简单有效算法。最后，推导了产生不可避免相位误差时回波信号的计算公式。我们展示了如何消除由这些错误引起的伪影并恢复原始图像。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Concepts in Magnetic Resonance Part A 物理-光谱学

CiteScore

0.90

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Concepts in Magnetic Resonance Part A brings together clinicians, chemists, and physicists involved in the application of magnetic resonance techniques. The journal welcomes contributions predominantly from the fields of magnetic resonance imaging (MRI), nuclear magnetic resonance (NMR), and electron paramagnetic resonance (EPR), but also encourages submissions relating to less common magnetic resonance imaging and analytical methods. Contributors come from academic, governmental, and clinical communities, to disseminate the latest important experimental results from medical, non-medical, and analytical magnetic resonance methods, as well as related computational and theoretical advances. Subject areas include (but are by no means limited to): -Fundamental advances in the understanding of magnetic resonance -Experimental results from magnetic resonance imaging (including MRI and its specialized applications) -Experimental results from magnetic resonance spectroscopy (including NMR, EPR, and their specialized applications) -Computational and theoretical support and prediction for experimental results -Focused reviews providing commentary and discussion on recent results and developments in topical areas of investigation -Reviews of magnetic resonance approaches with a tutorial or educational approach