University of Connecticut Health Center , Farmington, Connecticut 06030-3305, United States.
Acc Chem Res. 2014 Feb 18;47(2):708-17. doi: 10.1021/ar400244v. Epub 2014 Jan 9.
NMR spectroscopy is one of the most powerful and versatile analytic tools available to chemists. The discrete Fourier transform (DFT) played a seminal role in the development of modern NMR, including the multidimensional methods that are essential for characterizing complex biomolecules. However, it suffers from well-known limitations: chiefly the difficulty in obtaining high-resolution spectral estimates from short data records. Because the time required to perform an experiment is proportional to the number of data samples, this problem imposes a sampling burden for multidimensional NMR experiments. At high magnetic field, where spectral dispersion is greatest, the problem becomes particularly acute. Consequently multidimensional NMR experiments that rely on the DFT must either sacrifice resolution in order to be completed in reasonable time or use inordinate amounts of time to achieve the potential resolution afforded by high-field magnets. Maximum entropy (MaxEnt) reconstruction is a non-Fourier method of spectrum analysis that can provide high-resolution spectral estimates from short data records. It can also be used with nonuniformly sampled data sets. Since resolution is substantially determined by the largest evolution time sampled, nonuniform sampling enables high resolution while avoiding the need to uniformly sample at large numbers of evolution times. The Nyquist sampling theorem does not apply to nonuniformly sampled data, and artifacts that occur with the use of nonuniform sampling can be viewed as frequency-aliased signals. Strategies for suppressing nonuniform sampling artifacts include the careful design of the sampling scheme and special methods for computing the spectrum. Researchers now routinely report that they can complete an N-dimensional NMR experiment 3(N-1) times faster (a 3D experiment in one ninth of the time). As a result, high-resolution three- and four-dimensional experiments that were prohibitively time consuming are now practical. Conversely, tailored sampling in the indirect dimensions has led to improved sensitivity. Further advances in nonuniform sampling strategies could enable further reductions in sampling requirements for high resolution NMR spectra, and the combination of these strategies with robust non-Fourier methods of spectrum analysis (such as MaxEnt) represent a profound change in the way researchers conduct multidimensional experiments. The potential benefits will enable more advanced applications of multidimensional NMR spectroscopy to study biological macromolecules, metabolomics, natural products, dynamic systems, and other areas where resolution, sensitivity, or experiment time are limiting. Just as the development of multidimensional NMR methods presaged multidimensional methods in other areas of spectroscopy, we anticipate that nonuniform sampling approaches will find applications in other forms of spectroscopy.
NMR 光谱学是化学家可用的最强大和多功能的分析工具之一。离散傅里叶变换 (DFT) 在现代 NMR 的发展中发挥了重要作用,包括对表征复杂生物分子至关重要的多维方法。然而,它存在着众所周知的局限性:主要是从短数据记录中获得高分辨率光谱估计的困难。由于执行实验所需的时间与数据样本数成正比,因此该问题会给多维 NMR 实验带来采样负担。在磁场较高的情况下,光谱色散最大,问题变得尤为严重。因此,依赖 DFT 的多维 NMR 实验必须要么牺牲分辨率以便在合理的时间内完成,要么使用过多的时间来实现高场磁铁提供的潜在分辨率。最大熵 (MaxEnt) 重建是非傅里叶光谱分析方法,可从短数据记录中提供高分辨率光谱估计。它也可用于不均匀采样数据集。由于分辨率主要由采样的最大演化时间决定,因此不均匀采样能够实现高分辨率,同时避免在大量演化时间上均匀采样的需要。奈奎斯特采样定理不适用于不均匀采样数据,并且使用不均匀采样时出现的伪影可以视为频率混淆信号。抑制不均匀采样伪影的策略包括采样方案的精心设计和计算光谱的特殊方法。研究人员现在经常报告说,他们可以将 N 维 NMR 实验的速度提高 3(N-1) 倍(在九分之一的时间内完成 3D 实验)。结果,高分辨率的三维和四阶实验现在变得可行。相反,在间接维度中进行定制采样可以提高灵敏度。在不均匀采样策略方面的进一步进展可能会进一步降低高分辨率 NMR 光谱的采样要求,并且将这些策略与稳健的非傅里叶光谱分析方法(如 MaxEnt)相结合,代表了研究人员进行多维实验方式的深刻变化。潜在的好处将使多维 NMR 光谱学的更高级应用能够研究生物大分子、代谢组学、天然产物、动态系统和其他分辨率、灵敏度或实验时间受限的领域。正如多维 NMR 方法的发展预示着其他光谱领域的多维方法一样,我们预计不均匀采样方法将在其他形式的光谱学中得到应用。