Chemical-Shift-Selective Acquisition of Multiple-Quantum-Filtered23Na Signal

K.J. Jung , J. Katz
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引用次数: 6

Abstract

Equations describing the multiple-quantum (MQ) signal produced by an MQ pulse sequence are systematically derived in both absence and presence of refocusing RF pulses. When the RF pulses in an MQ pulse sequence satisfy certain conditions, these equations may be arranged in a factorized form. The off-resonance effects on the MQ signal due to chemical shift can then be analyzed separately during the preparation and evolution times. Using the reformulated equations, the dependence of the amplitude of an MQ signal on the phase shift induced by the resonance offset during the preparation and evolution times is demonstrated. By use of the new equations, it is shown that the off-resonance effects, occurring during both the preparation and evolution times, may be described in terms of the same physical process, i.e., interference between echo and antiecho. In applying the off-resonance effects for the elimination of the MQ signal in the presence of chemical shift, it is possible to suppress the MQ signal over a wider off-resonance bandwidth by use of the nonrefocused preparation and evolution times than by use of a single time. Furthermore, by taking an alternative approach in deriving the equations, the interference between echo and antiecho due to the resonance offset is shown to be insensitive to the flip angle of the creation RF pulse (usually the second π/2 RF pulse). The theoretical findings were experimentally verified by use of a phantom containing sodium in agarose.

多量子滤波23na信号的化学位移选择性采集
系统地推导了在无重聚焦射频脉冲和有重聚焦射频脉冲两种情况下由多量子脉冲序列产生的多量子信号的方程。当MQ脉冲序列中的射频脉冲满足一定条件时,这些方程可以被分解成因式。由于化学位移对MQ信号的非共振效应可以在准备和演化期间分别进行分析。利用重新表述的方程,证明了MQ信号的振幅在制备和演化过程中与共振偏移引起的相移的关系。利用新方程表明,在制备和演化过程中发生的非共振效应可以用相同的物理过程来描述,即回波和反回波之间的干扰。在应用非共振效应来消除存在化学位移的MQ信号时,通过使用非重新聚焦的准备和演化时间,可以在更宽的非共振带宽上抑制MQ信号,而不是使用单一时间。此外,通过采用另一种方法推导方程,由于共振偏移引起的回波和反回波之间的干扰对创建RF脉冲(通常是第二个π/2 RF脉冲)的翻转角度不敏感。用琼脂糖中含钠的幻体对理论结果进行了实验验证。
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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