MICROWAVE-ASSISTED SYNTHESIS AND SPECTROSCOPIC PROPERTIES OF NOVEL PYRIDINE-BASED FLUORESCENT MOLECULAR PROBES

Proceedings 17th International Conference on Microwave and High Frequency Heating Pub Date : 2019-09-09 DOI:10.4995/ampere2019.2019.9829

P. Fiedor, J. Ortyl, Mariusz Galek

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Abstract

Fluorescent molecular probes become interesting analytical tools in determination and labeling of chemical compounds and physical properties such as viscosity and polarity. Currently known fluorescent molecular probes can selectively and regardless of the environment detect only few molecules, and applicability in determination of micro- viscosity and micro-polarity are limited to narrow range and specific condition, therefore design and synthesis of novel molecular probes with extended range of operation are highly needed [1]. Traditional synthesis of 2-amino-4,6-diphenyl-pyridine-3-carbonitrile’s requires two step reaction with long heating time or and toxic solvent. By application of microwave irradiation, reaction time can be firmly shortened with the same or higher efficiency [2]. Derivatives of 2-amino-4,6-diphenyl-pyridine-3-carbonitrile can find application in different fields of science. Depending on the structure of fluorophore, those compounds exhibit high sensitivity to changes in polarity and viscosity of environment, also concentration of specific cations, and pH can be determined by measuring of fluorescence spectrum.

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新型吡啶基荧光分子探针的微波辅助合成及其光谱性质

荧光分子探针成为测定和标记化合物和物理性质(如粘度和极性)的有趣的分析工具。目前已知的荧光分子探针只能选择性地、不受环境影响地检测少量分子，在测定微粘度和微极性方面的适用性也局限于较窄的范围和特定的条件，因此迫切需要设计和合成具有更大操作范围的新型分子探针[1]。传统的2-氨基-4,6-二苯基吡啶-3-碳腈的合成需要两步反应，且加热时间长，溶剂有毒。应用微波辐照，可以在相同或更高的效率下坚定地缩短反应时间[2]。2-氨基-4,6-二苯基吡啶-3-碳腈的衍生物可以在不同的科学领域得到应用。根据荧光团的结构，这些化合物对环境的极性和粘度变化以及特定阳离子的浓度变化具有很高的敏感性，并且可以通过测量荧光光谱来确定pH值。

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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Proceedings 17th International Conference on Microwave and High Frequency Heating

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