纳米粒子辅助核磁共振波谱:化学传感的视角

IF 7.3 2区 化学 Q2 CHEMISTRY, PHYSICAL
Federico De Biasi, Fabrizio Mancin, Federico Rastrelli
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引用次数: 10

摘要

检测混合物中目标化合物的传感方法在许多不同的情况下都很重要,从医学诊断到环境分析和质量评估。理想情况下,这种检测方法应允许对目标进行识别和量化,最大限度地减少假阳性的可能性。除了极少数例外,大多数可用的传感技术依赖于分析物与某些检测器的选择性相互作用,这反过来又产生一个信号作为相互作用的结果。因此,这种方法提供了关于目标的间接信息,通常通过与已知标准的比较(如果有的话)或通过传感器系统本身的选择性来确保目标的身份。采用一种不同的方法,核磁共振化学传感旨在以(完整的)核磁共振谱的形式直接从分析物中产生信号。通过这种方式,不仅可以明确地确定目标,而且还可以识别和分配未知物种的结构。在这篇综述中,我们展示了如何弛豫和扩散为基础的核磁共振技术,在适当的纳米颗粒的辅助下,可以用来编辑混合物的1H核磁共振谱和提取特定目标化合物的信号。单层保护的纳米颗粒,尤其是由金制成的纳米颗粒,非常适合这项任务,因为它们提供了一种通用的、蛋白质大小的支持来构建或整合超分子受体。值得注意的是,纳米颗粒涂层的自组织和多功能特性允许利用不同种类的非共价相互作用,为几乎任何类型的分子提供定制的结合位点。从核磁共振的角度来看,体积较大的纳米颗粒平移和旋转扩散速率的降低提供了一种方法来操纵单层自旋的状态,并建立一个可以选择性地转移到相互作用的分析物的磁化库。此外,涂层分子的低相关时间和增强的刚性(由于它们在粒子表面的接枝和拥挤)促进了有效的自旋扩散,这在饱和转移实验中很有用。核磁共振实验和纳米受体的优化组合最终可以在微摩尔浓度范围内检测相关分析物,为在诊断领域及其他领域的应用铺平道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Nanoparticle-assisted NMR spectroscopy: A chemosensing perspective

Nanoparticle-assisted NMR spectroscopy: A chemosensing perspective

Sensing methodologies for the detection of target compounds in mixtures are important in many different contexts, ranging from medical diagnosis to environmental analysis and quality assessment. Ideally, such detection methods should allow for both identification and quantification of the targets, minimizing the possibility of false positives. With very few exceptions, most of the available sensing techniques rely on the selective interaction of the analyte with some detector, which in turn produces a signal as a result of the interaction. This approach hence provides indirect information on the targets, whose identity is generally ensured by comparison with known standards, if available, or by the selectivity of the sensor system itself. Pursuing a different approach, NMR chemosensing aims at generating signals directly from the analytes, in the form of a (complete) NMR spectrum. In this way, not only are the targets unequivocally identified, but it also becomes possible to identify and assign the structures of unknown species.

In this review we show how relaxation- and diffusion-based NMR techniques, assisted by appropriate nanoparticles, can be used to edit the 1H NMR spectrum of a mixture and extract the signals of specific target compounds. Monolayer-protected nanoparticles, in particular those made from gold, are well suited to this task because they provide a versatile, protein-size support to build or incorporate supramolecular receptors. Remarkably, the self-organized and multifunctional nature of the nanoparticle coating allows exploitation of different kinds of non-covalent interactions, to provide tailored binding sites for virtually any class of molecules.

From the NMR standpoint, the reduced translational and rotational diffusion rates of bulky nanoparticles offer a way to manipulate the states of the monolayer spins and build a reservoir of magnetization that can be selectively transferred to the interacting analytes. In addition, the low correlation time and the enhanced rigidity of the coating molecules (due to their grafting and crowding on the particle surface) promote efficient spin diffusion, useful in saturation transfer experiments. The optimized combination of NMR experiments and nanoreceptors can ultimately allow the detection of relevant analytes in the micromolar concentration range, paving the way to applications in the diagnostic field and beyond.

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来源期刊
CiteScore
14.30
自引率
8.20%
发文量
12
审稿时长
62 days
期刊介绍: Progress in Nuclear Magnetic Resonance Spectroscopy publishes review papers describing research related to the theory and application of NMR spectroscopy. This technique is widely applied in chemistry, physics, biochemistry and materials science, and also in many areas of biology and medicine. The journal publishes review articles covering applications in all of these and in related subjects, as well as in-depth treatments of the fundamental theory of and instrumental developments in NMR spectroscopy.
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