Multifunctional integration of biomass-derived porous carbon and zirconium dioxide for electrochemical sensing analysis of methyl parathion

IF 4 2区农林科学 Q2 CHEMISTRY, APPLIED

Journal of Food Composition and Analysis Pub Date : 2024-02-09 DOI:10.1016/j.jfca.2024.106067

Jiale Han , Mengyuan Zhao , Fang Li , Meimei Guo , Yunhang Liu , Qiwen Ran , Zhankui Wang , Hongyuan Zhao

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引用次数: 0

Abstract

We developed an economical and environment-friendly technique for preparing the expired mung bean-derived porous carbon (EMBPC), which possessed large specific surface area and 3D interlinked carbon conductive network. Zirconium dioxide (ZrO₂) nanoparticles were further incorporated into the porous structure of EMBPC to form the EMBPC@ZrO₂ composite, which was served as electrode sensitizer for the fabrication of EMBPC@ZrO₂/GCE sensor. EMBPC exhibited superior conductivity property and large electroactive area, which helped enhance the charge transfer efficiency between electrolyte and sensing electrode. ZrO₂ nanoparticles with good biocompatibility achieved the efficient adsorption of methyl parathion (MP) owing to the recognition of ZrO₂ towards the phosphate groups of MP. Furthermore, EMBPC with porous carbon conductive structure could make up for the inherent disadvantage of ZrO₂ nanoparticles in the term of electrical conductivity. The EMBPC@ZrO₂/GCE sensor achieved the highly sensitive MP detection (LOD: 8.77 nM) in linear MP concentration range of 0.01–10 μM. The satisfactory practical property was realized at the EMBPC@ZrO₂/GCE sensor with satisfactory recovery rates of 91.95–124.72% and low RSD% of 1.21–3.35% for the electrochemical detection of MP in food samples.

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生物质多孔碳和二氧化锆的多功能集成用于甲基对硫磷的电化学传感分析

我们开发了一种经济环保的过期绿豆衍生多孔碳（EMBPC）制备技术，它具有大比表面积和三维互连碳导电网络。二氧化锆（ZrO2）纳米颗粒被进一步加入到EMBPC的多孔结构中，形成了EMBPC@ZrO2复合材料，并将其作为电极敏化剂用于制造EMBPC@ZrO2/GCE传感器。EMBPC 具有优异的导电性能和较大的电活性面积，有助于提高电解质与传感电极之间的电荷转移效率。具有良好生物相容性的 ZrO2 纳米粒子能高效吸附甲基对硫磷（MP），这是因为 ZrO2 能识别甲基对硫磷的磷酸基团。此外，具有多孔碳导电结构的 EMBPC 可以弥补 ZrO2 纳米粒子在导电性方面的固有缺点。EMBPC@ZrO2/GCE 传感器在 0.01-10 μM 的线性 MP 浓度范围内实现了对 MP 的高灵敏度检测（LOD：8.77 nM）。EMBPC@ZrO2/GCE 传感器的实用性能令人满意，在电化学检测食品样品中 MP 的回收率为 91.95-124.72%，RSD% 低至 1.21-3.35%。

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来源期刊

Journal of Food Composition and Analysis 工程技术-食品科技

CiteScore

6.20

自引率

11.60%

发文量

601

审稿时长

53 days

期刊介绍： The Journal of Food Composition and Analysis publishes manuscripts on scientific aspects of data on the chemical composition of human foods, with particular emphasis on actual data on composition of foods; analytical methods; studies on the manipulation, storage, distribution and use of food composition data; and studies on the statistics, use and distribution of such data and data systems. The Journal''s basis is nutrient composition, with increasing emphasis on bioactive non-nutrient and anti-nutrient components. Papers must provide sufficient description of the food samples, analytical methods, quality control procedures and statistical treatments of the data to permit the end users of the food composition data to evaluate the appropriateness of such data in their projects. The Journal does not publish papers on: microbiological compounds; sensory quality; aromatics/volatiles in food and wine; essential oils; organoleptic characteristics of food; physical properties; or clinical papers and pharmacology-related papers.