Yong Jonathan R J, Kupče Ēriks, Claridge Tim D W
Chemistry Research Laboratory, Department of Chemistry, University of Oxford, Mansfield Road, Oxford OX1 3TA, United Kingdom; The Alan Turing Institute, The British Library, 96 Euston Road, London NW1 2DB, United Kingdom(1).
Bruker UK Ltd, R&D, Coventry CV4 9GH, United Kingdom; Latvian Academy of Sciences, Akadēmijas Laukums 1, Riga LV-1050, Latvia(1).
J Magn Reson. 2024 Oct;367:107759. doi: 10.1016/j.jmr.2024.107759. Epub 2024 Aug 24.
NMR supersequences, as exemplified by the NOAH (NMR by Ordered Acquisition using H detection) technique, are a powerful way of acquiring multiple 2D data sets in much shorter durations. This is accomplished through targeted excitation and detection of the magnetisation belonging to specific isotopologues ('magnetisation pools'). Separately, the HSQC-COSY experiment has recently seen an increase in popularity due to the high signal dispersion in the indirect dimension and the removal of ambiguity traditionally associated with HSQC-TOCSY experiments. Here, we describe how the HSQC-COSY experiment can be integrated as a 'module' within NOAH supersequences. The benefits and drawbacks of several different pulse sequence implementations are discussed, with a particular focus on how sensitivities of other modules in the same supersequence are affected.
以NOAH(利用氢检测的有序采集核磁共振)技术为例的核磁共振超序列,是在更短时间内获取多个二维数据集的有效方法。这是通过对属于特定同位素异构体(“磁化池”)的磁化进行靶向激发和检测来实现的。另外,由于间接维度中的高信号分散以及消除了传统上与HSQC-TOCSY实验相关的模糊性,HSQC-COSY实验近来越来越受欢迎。在此,我们描述了如何将HSQC-COSY实验作为一个“模块”集成到NOAH超序列中。讨论了几种不同脉冲序列实现方式的优缺点,特别关注同一超序列中其他模块的灵敏度如何受到影响。
