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共价有机骨架材料在有毒有害物质萃取中的应用进展
引用本文:张文敏,刘冠城,马文德,方敏,张兰. 共价有机骨架材料在有毒有害物质萃取中的应用进展[J]. 色谱, 2022, 40(7): 600-609. DOI: 10.3724/SP.J.1123.2021.12004
作者姓名:张文敏  刘冠城  马文德  方敏  张兰
作者单位:1.闽江师范高等专科学校, 福建 福州 3501082.福州大学, 食品安全与生物分析教育部重点实验室, 福建 福州 350116
基金项目:福州市科技计划项目(2019-S-66);福建省教育厅中青年教师教育科研项目(JAT201259)
摘    要:有毒有害物质的排放以及其可能具有的持久性和生物蓄积性,时刻危及人体健康甚至生命。因此,对环境、饮用水、食物和日用品中的有毒有害物质进行分析检测十分重要。对于复杂样品中痕量有毒有害物质的分析,样品预处理是一个至关重要的环节,直接影响分析方法的灵敏度和准确性。在有毒有害物质萃取中广泛应用的预处理技术包括固相萃取(SPE)、固相微萃取(SPME)、分散固相萃取(DSPE)、磁固相萃取(MSPE)等。在上述样品预处理技术中,吸附剂材料是最为核心的部分,它决定了预处理方法的选择性和效率。近年来,共价有机骨架(covalent organic frameworks,COFs)材料因其具有形貌结构多样、比表面积高、孔径可调、稳定性良好等优点,在样品预处理领域受到越来越多的关注。然而,COFs材料在萃取有毒有害物质方面的应用仍存在一些问题需要解决:(1)多数COFs是高度疏水的,这限制了它们在水基样品中的分散性,导致不良的萃取效果;(2)COFs材料主要依靠π-π堆积等相互作用对疏水性目标物进行高效萃取,但不利于极性有毒有害物质的萃取;(3)多数COFs材料存在合成工艺复杂、生产成本高、量产困难等问题。该文对近几年COFs材料在有毒有害物质萃取过程中的研究进展进行了总结和评述。最后,展望了COFs材料在该领域中的应用前景,为进一步研究基于COFs材料的预处理技术提供了参考。

关 键 词:持久性有机污染物  塑化剂  农药  药物  综述  共价有机骨架材料
收稿时间:2021-12-06

Application progress of covalent organic framework materials in extraction of toxic and harmful substances
ZHANG Wenmin,LIU Guancheng,MA Wende,FANG Min,ZHANG Lan. Application progress of covalent organic framework materials in extraction of toxic and harmful substances[J]. Chinese journal of chromatography, 2022, 40(7): 600-609. DOI: 10.3724/SP.J.1123.2021.12004
Authors:ZHANG Wenmin  LIU Guancheng  MA Wende  FANG Min  ZHANG Lan
Affiliation:1. Minjiang Teachers College, Fuzhou 350108, China2. Ministry of Education Key Laboratory for Analytical Science of Food Safety and Biology, Fuzhou University, Fuzhou 350116, China
Abstract:Toxic and hazardous substances constitute a category of compounds that are potentially hazardous to humans, other organisms, and the environment. These substances include pesticides (benzoylureas, pyrethroids, neonicotinoids), persistent organic pollutants (polycyclic aromatic hydrocarbons, polychlorinated biphenyls, perfluorinated compounds), plasticizers (phthalate esters, phenolic endocrine disruptors), medicines (sulfonamides, non-steroid anti-inflammatory drugs, tetracyclines, fluoroquinone antibiotics), heterocyclic aromatic amines, algal toxins, and radioactive substances. Discharge of these toxic and harmful substances, as well as their possible persistence and bioaccumulation, pose a major risk to human health, often to the extent of being life-threatening. Therefore, it is important to analyze and detect toxic and hazardous substances in the environment, drinking water, food, and daily commodities. Sample pretreatment is an imperative step in most of the currently used analytical methods, especially in the analysis of trace toxic and harmful substances in complex samples. An efficient and fast sample pretreatment technology not only helps improve the sensitivity, selectivity, reproducibility, and accuracy of analytical methods, but also avoids contamination of the analytical instruments and even damages the performance and working life of instruments. Sample pretreatment techniques widely used in the extraction of toxic and hazardous substances include solid-phase extraction (SPE), solid-phase microextraction (SPME), and dispersed solid-phase extraction (DSPE). The adsorbent material plays a key role in these pretreatment techniques, thereby determining their selectivity and efficiency. In recent years, covalent organic frameworks (COFs) have attracted increasing attention in sample pretreatment. COFs represent an exciting new class of porous crystalline materials constructed via the strong covalent bonding of organic building units through a reversible condensation reaction. COFs present four advantages: (1) precise control over structure type and pore size by consideration of the target molecular structure based on the connectivity and shape of the building units; (2) post-synthetic modification for chemical optimization of the pore interior toward optimized interaction with the target; (3) straightforward scalable synthesis; (4) feasible formation of composites with magnetic nanoparticles, carbon nanotubes, graphene, silica, etc., which is beneficial to enhance the performance of COFs and meet the requirement of diverse pretreatment technologies. Because of the well-defined crystalline porous structures and tailored functionalities, COFs have excellent potential for use in target extraction. However, some issues need to be addressed for the application of COFs in the extraction of toxic and hazardous substances. (1) For the sample matrix, most of the reported COFs are highly hydrophobic, which limits their dispersibility in water-based samples, leading to poor extraction performance. COFs with good dispersibility in water-based samples are urgently required. (2) Besides, COFs rely on hydrophobic interaction, size repulsion, π-π stacking, and Van der Waals forces to extract target substances, but they are not effective for some polar targets. Thus, it is necessary to develop COFs with high affinity for polar toxic and hazardous substances. (3) Methods for the synthesis of COFs have evolved from solvothermal methods to room-temperature methods, mechanical grinding, microwave-assisted synthesis, ion thermal methods, etc. Most of the existing methods are time-consuming, laborious, and environmentally unfriendly. The starting materials are too expensive to prepare COFs in large quantities. More effort is required to improve the synthesis efficiency and overcome the obstacles in the application of COFs for extraction. This article summarizes and reviews the research progress in COFs toward the extraction of toxic and hazardous substances in recent years. Finally, the application prospects of COFs in this field are summarized, which serves as a reference for further research into pretreatment technologies based on COFs.
Keywords:covalent organic frameworks  pesticides  persistent organic pollutants  plasticizer  medicines  review  
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