一种AIE活性磺酰基苯胺衍生的希夫碱，用于检测叶酸，血红蛋白和葡萄糖†

IF 2.7 3区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

New Journal of Chemistry Pub Date : 2024-12-18 DOI:10.1039/D4NJ03833A

Dhvani A. Patel, Bigyan R. Jali and Suban K. Sahoo

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引用次数: 0

摘要

叶酸（又称维生素B9）的过量摄入或缺乏会导致多种健康问题。因此，需要优先研究开发简便的FA检测分析方法。本文通过将4,4′-磺基二苯胺与两种水杨醛缩合而成的v形聚集诱导发光（AIE）发光材料SDASA。由于AIE和ESIPT的联合作用，当HEPES缓冲液（H2O, 10 mM, pH 7.4）的分数从80%增加到95%时，DMSO中的弱荧光SDASA呈现黄色发射。SEM和DLS分析证实了SDASA自聚集体的形成。采用AIEgen SDASA （fHEPES 95%）作为探针1检测FA。AIEgen SDASA （λem = 550 nm, λex = 390 nm）在475 nm处发生蓝移和荧光增强。DFT、荧光寿命、zeta电位、DLS和紫外-可见吸收研究结果表明，FA与SDASA的相互作用抑制了SDASA的分子内电荷转移和聚集形态。探针1可检测FA浓度至0.83 μM。SDASA在DMSO中的进一步研究表明，与Zn2+离子络合后，在525 nm处有很强的绿色发射。原位生成的SDASA-Zn2 +配合物作为探针2用于血红蛋白和葡萄糖的荧光关闭检测，检测限分别为0.57 nM和0.32 μM。最后，通过检测真实血清中的选择性分析物来检验所开发探针的分析效用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

An AIE active sulfonyldianiline derived Schiff base for the detection of folic acid, hemoglobin, and glucose†

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An AIE active sulfonyldianiline derived Schiff base for the detection of folic acid, hemoglobin, and glucose†

The excessive intake or deficiency of folic acid (FA), also known as vitamin B₉, can lead to several health problems. Therefore, significant research priority is required to develop facile analytical methods for FA detection. Herein, a V-shaped aggregation-induced emission (AIE) luminogen SDASA was introduced by condensing 4,4′-sulfonyldianiline with two equivalents of salicylaldehyde. The weakly fluorescent SDASA in DMSO showed yellow emission upon increasing the fractions of HEPES buffer (H₂O, 10 mM, pH 7.4) from 80% to 95% because of the combined effects of AIE and ESIPT. The formation of self-aggregates of SDASA was supported by SEM and DLS analyses. AIEgen SDASA (f_HEPES 95%) was employed as probe 1 for FA detection. The fluorescence emission of AIEgen SDASA (λ_em = 550 nm, λ_ex = 390 nm) was blue-shifted and enhanced at 475 nm by FA. The results of DFT, fluorescence lifetime, zeta potential, DLS, and UV-vis absorption studies revealed that the interaction that occurred between FA and SDASA inhibited the intramolecular charge transfer and aggregate morphology of SDASA. With probe 1, the FA concentration can be detected down to 0.83 μM. Further studies with SDASA in DMSO showed strong green emission at 525 nm upon complexation with Zn²⁺ ions. The in situ generated SDASA–Zn²⁺ complex was used as probe 2 for the fluorescent turn-off detection of hemoglobin and glucose with a detection limit of 0.57 nM and 0.32 μM, respectively. Finally, the analytical utility of the developed probes was examined by detecting selective analytes in real blood serum.