Nuclear Magnetic Resonance for Targeted Metabolomics and Biochemical Sensor

Q3 Pharmacology, Toxicology and Pharmaceutics

Jordan Journal of Pharmaceutical Sciences Pub Date : 2023-07-24 DOI:10.35516/jjps.v16i2.1519

Ahmed Bahti, A. Telfah, Nour Sharar, Hanan Jafar, R. Hergenröder

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引用次数: 0

Abstract

NMR spectroscopy is quantitative, highly reproducible, non-selective and non-destructive. However, NMR costs and complexity hinder a use as point-of-care and biochemical sensor instrumentation. Low field NMR (LF-NMR) is an inexpensive and low footprint technique to obtain physical, chemical, electronic and structural information on small molecules, but suffers from poor spectral dispersion, especially when applied to the analysis of mixtures. Subspectral editing employing optimal control pulses is a suitable approach to cope with the severe signal superpositions in complex mixture spectra at low field. We have calculated the optimal control pulse shapes at 0.5 T NMR frequency using the Krotov algorithm. Downsizing the complexity of the algorithm from exponential to polynomial is shown to be possible by using a system approach with each system corresponding to a (small) molecule. In this way compound selective excitation pulses can be calculated. The signals of substructures of the cyclopentenone molecule were excited using optimal control pulses calculated by the Krotov algorithm demonstrating the feasibility of subspectral editing. Likewise, for a mixture of benzoic acid and alanine, editing of the signals of either benzoic acid or alanine employing optimal control pulses was shown to be possible. The obtained results are promising and can be extended to the targeted analysis of complex mixtures such as biofluids or metabolic samples at low field strengths opening access for benchtop NMR to point of care settings. Moreover, the LF-NMR was improved to allow a unique detection and reliable quantification of metabolites in biofluids like blood, urine, cerebrospinal fluid, or even tissue. In contrast to standard large scale NMR equipment the portable LF-NMR allows for an analysis of the chemical composition of biofluid samples directly at the patient (point-of-care). LF-NMR can be freely programmable for detecting and detecting and sensing sets of small molecules which deliver information on the health status of a person. Such an analytical tool would be useful for the prediction, diagnosis, monitoring and prognosis of diseases, and for supervision of therapeutic interventions.

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核磁共振用于靶向代谢组学和生化传感器

核磁共振光谱是定量的，高重复性的，非选择性和非破坏性的。然而，核磁共振的成本和复杂性阻碍了它作为即时护理和生化传感器仪器的使用。低场核磁共振(LF-NMR)是一种廉价、低足迹的技术，可获得小分子的物理、化学、电子和结构信息，但其光谱色散较差，特别是在用于分析混合物时。采用最优控制脉冲进行子谱编辑是处理低场复杂混合光谱中严重信号叠加的有效方法。我们利用Krotov算法计算了0.5 T核磁共振频率下的最优控制脉冲形状。通过使用系统方法，每个系统对应一个(小)分子，可以将算法的复杂性从指数级降低到多项式级。用这种方法可以计算复合选择性激励脉冲。利用Krotov算法计算的最优控制脉冲激发环戊酮分子的子结构信号，证明了子谱编辑的可行性。同样，对于苯甲酸和丙氨酸的混合物，使用最优控制脉冲编辑苯甲酸或丙氨酸的信号被证明是可能的。所获得的结果是有希望的，可以扩展到复杂混合物的目标分析，如生物流体或代谢样品在低场强打开访问台式核磁共振到护理点设置。此外，LF-NMR经过改进，可以对血液、尿液、脑脊液甚至组织等生物体液中的代谢物进行独特的检测和可靠的定量。与标准的大型核磁共振设备相比，便携式LF-NMR允许直接在患者(护理点)分析生物流体样品的化学成分。LF-NMR可以自由编程，用于检测、检测和传感小分子集，这些小分子集可以传递关于人的健康状况的信息。这种分析工具将有助于疾病的预测、诊断、监测和预后，以及对治疗干预措施的监督。

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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来源期刊

Jordan Journal of Pharmaceutical Sciences Pharmacology, Toxicology and Pharmaceutics-Pharmaceutical Science

CiteScore

1.70

自引率

0.00%

发文量

期刊介绍： The Jordan Journal of Pharmaceutical Sciences (JJPS) is a scientific, bi-annual, peer-reviewed publication that will focus on current topics of interest to the pharmaceutical community at large. Although the JJPS is intended to be of interest to pharmaceutical scientists, other healthy workers, and manufacturing processors will also find it most interesting and informative. Papers will cover basic pharmaceutical and applied research, scientific commentaries, as well as views, reviews. Topics on products will include manufacturing process, quality control, pharmaceutical engineering, pharmaceutical technology, and philosophies on all aspects of pharmaceutical sciences. The editorial advisory board would like to place an emphasis on new and innovative methods, technologies, and techniques for the pharmaceutical industry. The reader will find a broad range of important topics in this first issue.