Water suppression 101 for benchtop NMR–An accessible guide and primer including fully interactive training videos

IF 2.624
Ronald Soong , William Wolff , Jacob Pellizzari , Katelyn Downey , Sarah Chen , Rajshree Ghosh Biswas , Monica Bastawrous , Benjamin Goerling , Venita Busse , Falko Busse , Colin Elliott , Agnes Haber , Alain Belguise , Myrna Simpson , Andre Simpson
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Abstract

Benchtop NMR is enjoying a renaissance with numerous manufacturers bringing products to the market over the last decade. The improved accessibility, lower cost of ownership and ease of use (vs high field NMR), is attracting new users into NMR spectroscopy, which is highly beneficial for the field in general. As benchtop NMR systems seldom require deuterated solvents, this allows samples to be analyzed “as is”, without extraction or alteration. However, many interesting samples, be it an organic reaction mixture, beer, or a biofluid, contain one or more solvent/water signals, which often require suppression. Due to the lower spectral dispersion of benchtop NMR's (vs high field) the frequency of solvent/water is much closer to the analytes of interest, making solvent suppression more challenging. As such, there is a conundrum, where novel users wish to analyze unaltered samples but are quickly faced with the challenge of water suppression, and the wealth of options in the high field literature can be overwhelming. It is important to note that all manufacturers offer some sort of automated water suppression that can be performed with a “single click” that are sufficient for “walk-up” applications or occasional users. This primer is aimed as an accessible guide to those wishing to take the next step and is suitable for users who; 1) would like to pick the optimal water suppression approach for their sample type and 2) wish to understand how water suppression works. The guide focuses on water suppression approaches that are easy to apply, namely presaturation based sequences, binomial sequences for aggressive suppression, and WET for multiple signal suppression, across a range of samples including sucrose standards, espresso, human blood serum and wine. The primer finishes with a flow chart that can be used to guide users in choosing the optimal water suppression approach for their specific sample type, with considerations, including exchangeable signals and the preservation of macromolecular signals, amongst others. In addition, the primer includes 3 fully interactive videos based on H5P technology, focusing on how to acquire data using the approaches described here. The videos include quizzes, with a first-person-perspective of the spectrometer software with interactive elements, as if the users were acquiring the data themselves. In summary, the primer is aimed at advanced undergraduates, graduate students, new users, or users wishing to expand their water/solvent suppression skills/knowledge using benchtop NMR.

Abstract Image

台式 NMR 的水抑制 101--包括完全交互式培训视频在内的简明指南和入门读物
台式 NMR 正在复兴,过去十年间,众多制造商向市场推出了各种产品。与高场 NMR 相比,台式 NMR 更容易获得、拥有成本更低且易于使用,因此吸引了更多新用户加入 NMR 光谱分析,这对整个领域都大有裨益。由于台式 NMR 系统很少需要氚代溶剂,因此可以对样品进行 "原样 "分析,无需提取或改变。然而,许多有趣的样品,无论是有机反应混合物、啤酒还是生物流体,都含有一个或多个溶剂/水信号,通常需要抑制这些信号。由于台式 NMR 的光谱弥散较低(与高场相比),溶剂/水的频率更接近相关分析物,因此溶剂抑制更具挑战性。因此,新用户希望分析未改变的样品,但很快就会面临水抑制的挑战,而高场文献中丰富的选择可能会让用户不知所措。值得注意的是,所有生产商都提供了某种 "一键式 "自动抑水功能,足以满足 "即用型 "应用或临时用户的需求。本入门指南旨在为那些希望迈出下一步的用户提供一份易懂的指南,适用于以下用户:1)希望为自己的样品类型选择最佳的水抑制方法;2)希望了解水抑制的工作原理。指南重点介绍了易于应用的水抑制方法,即基于预饱和度的序列、用于强力抑制的二项式序列和用于多信号抑制的 WET,适用于一系列样品,包括蔗糖标准品、浓咖啡、人体血清和葡萄酒。该入门指南最后附有一个流程图,可用于指导用户针对其特定样品类型选择最佳的水抑制方法,其中包括可交换信号和保留大分子信号等注意事项。此外,该入门指南还包括 3 个基于 H5P 技术的完全互动视频,重点介绍如何使用此处介绍的方法获取数据。这些视频包括小测验,以第一视角展示了光谱仪软件的互动元素,就像用户自己在获取数据一样。总之,该入门指南面向高年级本科生、研究生、新用户或希望使用台式 NMR 扩展水/溶剂抑制技能/知识的用户。
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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CiteScore
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