基于多酸主客体材料在检测香草酸中的应用<sup>*</sup>

李娜, 陈世旭, 张聪, 赵海燕, 崔敏, 孙宝, 李化凡, 张焕

doi:10.16155/j.0254-1793.2024-0113

药物分析杂志 >

2024 , Vol. 44 >Issue 9: 1638 - 1645

DOI: https://doi.org/10.16155/j.0254-1793.2024-0113

质量评价·技术研发

基于多酸主客体材料在检测香草酸中的应用^*

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1.河北科技大学理学院河北省表界面光电调控重点实验室,石家庄 050018;
2.河北省中医院,石家庄 050018

第一作者 Tel:(0311)81669959;E-mail:751877132@qq.com

^**张聪 Tel:(0311)81669959;E-mail:zhangcong0672@163.com
赵海燕 Tel:(0311)81669959;E-mail:yanzi977649230@163.com
张焕 Tel:(0311)69095009;E-mail:472441392@qq.com

收稿日期: 2024-02-23

网络出版日期: 2024-10-17

基金资助

^*河北省教育厅 (BJK2023068);河北省省级科技计划项目 (226Z7715G);河北省中医药管理局科研计划项目(2023039)

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Determination of vanillic acid based on POM-host guest materials^*

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1. Hebei Provincial Key Laboratory of Photoelectric Control on Sunface and Interface, College of Science, Hebei University of Science and Technology, Shijiazhuang 050018, China;
2. Hebei Province Chinese Medicine Hospital, Shijiazhuang 050018, China

Received date: 2024-02-23

Online published: 2024-10-17

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摘要

目的: 采用多金属氧酸盐基主客体框架材料修饰玻碳电极测定香草酸的浓度。方法: 按照多酸基主客体框架材料合成方法,选择钒取代的磷钼酸(PMoV)与MIL-100(Fe)复合,合成了一种稳定的基于多酸的主客体金属有机框架材料PMoV@MIL-100(Fe)。通过溶液法将金属纳米粒子与PMoV@MIL-100(Fe)复合,制备功能性复合材料PMoV@MIL-100(Fe)@Pt,并用来修饰玻碳电极,检测香草酸,制备香草酸电化学传感器。结果: 在最佳条件下,该香草酸电化学传感器表现出宽的线性范围和较高灵敏度。可以在温和的条件下对香草酸进行快速灵敏的检测,且具有出色的稳定性。结论: 本实验构建的电化学传感器为检测香草酸提供了新思路。

关键词： 多金属氧酸盐; 香草酸; 电化学传感器; 主客体; 多金属氧酸盐的金属有机骨架结构

本文引用格式

李娜, 陈世旭, 张聪, 赵海燕, 崔敏, 孙宝, 李化凡, 张焕 . 基于多酸主客体材料在检测香草酸中的应用^*[J]. 药物分析杂志, 2024 , 44(9) : 1638 -1645 . DOI: 10.16155/j.0254-1793.2024-0113

Abstract

Objective: To determine the concentration of vanillic acid by polyoxometal-based host-guest frame material modified glass carbon electrode. Methods: A stable polyacid-based host-guest metal-organic framework material PMoV@MIL-100(Fe) was synthesized by combining vanadium-substituted phosphomolybdic acid (PMoV) with MIL-100(Fe) according to the synthesis method of polyacid-based host-guest framework materials. Functional composite material PMoV@MIL-100(Fe)@Pt was prepared by composite metal nanoparticles with PMoV@MIL-100(Fe) by solution method, and was used to modify glassy carbon electrode, detect vanillic acid, and prepare vanillic acid electrochemical sensor. Results: Under optimal conditions, the vanillic acid electrochemical sensor showed wide linear range and high sensitivity. Rapid and sensitive detection of vanillic acid could be performed under mild conditions with excellent stability. Conclusion: The electrochemical sensor constructed in this experiment provides a new idea for the detection of vanillic acid.

Key words： polyoxometallate; vanillic acid; electrochemical sensor; host-guest; POMOFs

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