磁性共价有机骨架材料富集检测典型有机污染物的应用进展

doi:10.3724/SP.J.1123.2024.07020

摘要/Abstract

摘要：

痕量污染物因其在环境中的微量存在和基质的复杂性,难以直接通过仪器进行检测,对人类的健康构成潜在威胁。磁性固相萃取(MSPE)技术因具有操作简单、成本低廉、富集效率高等优势,在样品前处理领域一直备受关注。磁性固相萃取的研究聚焦于磁性材料的功能化,近年来研究者深入探索了磁性材料的功能化途径,将多种新兴材料引入磁性材料的修饰,有效拓展了磁性功能化材料的性能和应用领域。其中,磁性共价有机骨架材料(MCOFs)是一种具有代表性的材料,不仅具有比表面积大、稳定性高的特点,还兼具磁性材料的快速分离特性;可通过氢键作用、疏水作用、π-π共轭作用实现对目标物的快速、高效富集。本文重点综述了MCOFs的种类、合成方法及其在富集检测农药、内分泌干扰物(EDCs)及药物和个人护理产品(PPCPs)中的应用,并对该领域未来研究的发展方向进行了展望。

关键词: 磁性固相萃取, 磁性共价有机骨架材料, 农药, 内分泌干扰物, 药物及个人护理产品, 综述

Abstract:

Trace contaminants are toxic and their widespread presence in the environment potentially threatens human health. The levels of these pollutants are often difficult to determine directly using instruments owing to the complexities of environment matrices. Hence, pretreatment steps, such as sample purification and concentration, are key along with various processes that enhance the accuracy and sensitivity of the detection method. To date, researchers have successfully developed a variety of efficient and reliable sample-pretreatment techniques that are based on different principles. Among these, magnetic solid-phase extraction (MSPE) is a rapid and efficient sample-pretreatment technology that is based on the similar solid-phase-extraction (SPE) principle, which mainly enriches target analytes by exploiting their interactions with functional groups on the surfaces of magnetic materials, thereby achieving rapid separation when an external magnetic field is applied. MSPE has been a focus of attention in the environmental-sample-pretreatment, food-analysis, and other fields owing to advantages that include ease of operation, low cost, and high enrichment efficiency. The selection of the magnetic material is key to MSPE process because traditional magnetic materials exhibit certain functionality limitations. Accordingly, designing and synthesizing green and efficient functionalized magnetic materials have become a research focus in this field, with researchers having extensively explored multiple ways of preparing functionalized modified magnetic materials through the introduction of a variety of emerging materials, including metal-organic frameworks (MOFs), covalent organic frameworks (COFs), carbon nanotubes (CNTs), graphene oxide (GO), and other specific functional groups to modify magnetic materials and effectively expanded the applications scope of MSPE. Among these, COFs are porous crystalline materials consisting of light elements (C, N, H, O and B, etc.) linked through covalent bonds. COFs are mainly classified as imine COFs, boronic-acid COFs, triazine COFs, and ketenimine COFs according to bonding type. Moreover, it is worth mentioning that COFs can be synthesized from a number of monomers, and the functional groups exposed on the COF surface can also be used for further modification purposes. COFs are versatile and modifiable; consequently, they have attracted significant research attention, with a series of COF-functionalized magnetic materials having been designed and synthesized. The magnetic COFs (MCOFs) combine the advantages of COFs and magnetic materials. MCOFs are not only endowed with the large specific surface areas, high porosities, and good stabilities that are characteristic of COFs, but also exhibit the rapid separation and reusability characteristics of magnetic material, thereby quickly and efficiently enriching targets through hydrogen bonding, hydrophobicity, π-π stacking, and van der Waals forces, making them ideal sample-pretreatment materials. MCOFs have also been converted into more-versatile functional materials using post-modification strategies. Combining MCOFs with advanced analytical techniques, such as high performance liquid chromatography (HPLC) and gas chromatography-mass spectrometry (GC-MS) has effectively improved the limits of detection (LODs) for various analytes as well as method accuracy; these techniques have been widely used to enrich and detect trace pollutants. However, some material design and synthesis challenges remain and need to be overcome, despite the promising potential of MCOFs. Future research needs to focus on exploring novel synthetic strategies that reduce experimental costs and improve the functionalities of MCOFs while expanding their applicabilities to broader sample matrices. In this review, we first introduce and discuss the construction and functionalized designs of various MCOF composites, and then summarize their use in applications that include the enrichment and detection of pesticides, endocrine disruptors (EDCs), pharmaceuticals, and personal care products (PPCPs), and finally provide an outlook on future developmental prospects.

Key words: magnetic solid-phase extraction (MSPE), magnetic covalent organic framework (MCOFs), pesticide, endocrine disruptors (EDCs), pharmaceutical and personal care products (PPCPs), review

中图分类号:

O658

姜刘杉, 周庆祥. 磁性共价有机骨架材料富集检测典型有机污染物的应用进展[J]. 色谱, 2025, 43(2): 107-119.

JIANG Liushan, ZHOU Qingxiang. Recent progress in magnetic covalent organic framework materials for the enrichment and detection of typical organic pollutants[J]. Chinese Journal of Chromatography, 2025, 43(2): 107-119.

图/表 3

图1 (a)Fe3O4@TAPT-TFTA-COF的合成机理图[64]; (b)Fe3O4、(c)TAPT-TFTA-COF和(d)Fe3O4@TATP-TFTA-COF的透射电镜图[64]; (e)Fe3O4@COFs的合成及高效吸附去除TCS和TCC[65]; (f)花状磁性TpPa-1的合成及应用[53]; (g)NH2-Fe3O4和(h)磁性TpPa-1的透射电镜图[53]; (i)Fe3O4@PDA@TbBD的合成路线图[69]; (j)Fe3O4@PDA和(k)Fe3O4@PDA@TbBD的透射电镜图[69]

Fig. 1 (a) Synthetic diagram of Fe3O4@TAPT-TFTA-COF[64]; TEM images of (b) Fe3O4, (c) TAPT-TFTA-COF and (d) Fe3O4@TATP-TFTA-COF[64]; (e) synthesis of Fe3O4@COFs and efficient adsorption and removal of TCS and TCC[65]; (f) synthesis and application of magnetic flower-like TpPa-1[53]; TEM images of (g) NH2-Fe3O4 and (h) magnetic TpPa-1[53]; (i) synthetic route of Fe3O4@PDA@TbBD[69]; TEM images of (j) Fe3O4@PDA and (k) Fe3O4@PDA@TbBD[69] TAPT: 4,4',4″-(1,3,5-triazine-2,4,6-triyl)trianiline; TFTA: 2,3,5,6-tetrafluoroterephthalaldehyde; COF: covalent organic framework; TCS: triclosan; TCC: triclocarban; PDA: polydopamine.

图 2 (a)顺序合成后修饰法制备Zr4+固定化磁性COF的机理图[70]; (b)MCNC@COF-GSH微球的合成示意图[71]; (c)MCNCs@COF@PBA的合成及磁性富集糖肽的示意图[72]; (d)球形团簇结构MB-COF的合成示意图[75]

Fig. 2 (a) Mechanism diagram of preparing Zr4+-immobilized magnetic COFs through sequential post-synthetic modifications[70]; (b) synthetic schematic diagram of MCNC@COF-GSH microspheres[71]; (c) synthetic process of MCNCs@COF@PBA and magnetic enrichment of glycopeptides[72]; (d) schematic diagram of MB-COF with spherical cluster-like structure[75] MCNC: magnetic colloid nanocrystal cluster; GSH: glutathione; PBA: phenylboronic acid; MB: magnetic-based.

图3 (a)Fe3O4@v-COF的合成及磁性固相萃取苯并咪唑类杀虫剂[88]; (b)COF-SiO2@Fe3O4的合成及检测拟除虫菊酯类农药[54]; (c)Fe3O4@COF-(TpBD)的合成及磁性固相萃取多环芳烃的示意图[93]; (d)Fe3O4@SiO2@COF-(TpBD)的合成及磁性固相萃取杂环芳香胺流程图[94]; (e)Fe3O4@COF(TAPT-DHTA)的构建及磁性固相萃取水果中霉菌毒素[95]; (f)Fe3O4@SiO2@Tb-PDAN的制备及磁性固相萃取MALs[97]; (g)Fe3O4@SiO2@Ah-COF的合成及富集检测喹诺酮类抗生素[101]; (h)Fe3O4@SiO2@PDE-TAPB-COF的合成及磁性固相萃取磺胺类抗生素[103]

Fig. 3 (a) Schematic illustration of synthesized Fe3O4@v-COF and MSPE process for benzimidazole fungicides[88]; (b) synthesis of COF-SiO2@Fe3O4 and determination of pyrethroid pesticides[54]; (c) schematic diagram of Fe3O4@COF-(TpBD) and MSPE process for PAHs[93]; (d) flow chart for synthesizing Fe3O4@SiO2@COF-(TpBD) and MSPE of heterocyclic aromatic amines[94]; (e) construction of Fe3O4@COF(TAPT-DHTA) and MSPE of mycotoxins from fruits[95]; (f) preparation of Fe3O4@SiO2@Tb-PDAN and MSPE process for MALs[97]; (g) synthesis and enrichment of Fe3O4@SiO2@Ah-COF and enrichment detection of quinolone antibiotics[101]; (h) preparation of Fe3O4@SiO2@PDE-TAPB-COF and MSPE of sulfonamide antibiotics[103] V-COF: vinylene-linked COF; PAHs: polycyclic aromatic hydrocarbons; DHTA: 2,5-dihydroxyterephthalic acid; Tb: 1,3,5-triformylbenzene; PDAN: 1,4-phenylenediacetonitrile; MALs: macrolides; PDE: 2,6-pyridine dicarboxaldehyde.

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