B1-insensitive heteronuclear adiabatic polarization transfer for signal enhancement

Journal of Magnetic Resonance (1969) Pub Date : 1992-10-01 DOI:10.1016/0022-2364(92)90204-K

Hellmut Merkle, Haoran Wei, Michael Garwood, Kâmil Uǧurbil

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引用次数: 27

Abstract

A new B₁-insensitive pulse sequence, BINEPT (for B₁-insensitive nuclear enhancement through polarization transfer) is introduced that accomplishes signal enhancement for low-sensitivity nuclei through heteronuclear polarization transfer. Previously described methods for polarization transfer through J-ordered states such as INEPT [D. P. Burum and R. R. Ernst, J. Magn. Reson. 39, 163 (1980)] require homogeneous B₁ fields and carefully calibrated pulses to impart $π 2$ and π rotations in order to achieve the maximum possible signal enhancement. In contrast, BINEPT, which is based on recently introduced adiabatic plane-rotation pulses, can induce the desired enhancement over a very large range of B₁ magnitude and can be used even with surface coils that generate highly inhomogeneous B₁ fields. BINEPT is not simply the INEPT sequence with the conventional pulses replaced with their adiabatic plane-rotation pulse analogs. Rather, it is based on the variable-angle, adiabatic BIR-4 pulse [M. Garwood and Y. Ke, J. Magn. Reson. 94, 511 (1991)] and the principle that the evolution of spin states during intrapulse delays inserted in BIR-4 can determine the final rotation induced on magnetization vectors. The BINEPT technique is described theoretically in the rotating frame. Its performance is compared experimentally with INEPT using coils that generate homogeneous and inhomogeneous B₁ fields.

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用于信号增强的B1不敏感异核绝热极化转移

引入了一种新的B1不敏感脉冲序列BINEPT（用于通过极化转移实现B1不敏感核增强），该序列通过异核极化转移实现低灵敏度核的信号增强。先前描述的通过J有序态进行偏振转移的方法，如INEPT[D.P.Burum和R.R.Ernst，J.Magn.Reson.39163（1980）]，需要均匀的B1场和仔细校准的脉冲来施加π2和π旋转，以实现最大可能的信号增强。相反，基于最近引入的绝热平面旋转脉冲的BINEPT可以在非常大的B1幅度范围内引起所需的增强，并且甚至可以用于产生高度不均匀的B1场的表面线圈。BINEPT不是简单的INEPT序列，传统脉冲被它们的绝热平面旋转脉冲模拟物取代。相反，它是基于可变角度绝热BIR-4脉冲[M.Garwood和Y.Ke，J.Magn.Reson.94111（1991）]以及插入BIR-4中的脉冲内延迟期间自旋态的演变可以确定在磁化矢量上感应的最终旋转的原理。在旋转框架中对BINEPT技术进行了理论描述。它的性能与使用产生均匀和非均匀B1场的线圈的INEPT进行了实验比较。

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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Journal of Magnetic Resonance (1969)

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