亚胺类共价有机骨架材料在样品前处理中的应用

doi:10.3724/SP.J.1123.2021.04029

摘要/Abstract

摘要：

亚胺类共价有机骨架(I-COFs)是有机单体根据席夫碱(Schiff-base)反应原理缩合形成的一类新型多孔晶体有机材料。I-COFs具有骨架密度低、比表面积大、孔隙率高、单体种类丰富、孔径尺寸可控、结构可功能化、合成方法多样和物化稳定性好等优点。近年来,I-COFs已成为材料科学领域的研究前沿,并广泛用于气体吸附、存储、催化、传感、光电材料等方面。I-COFs材料优异的物理化学性能使其非常适于用作复杂样品中痕量目标物的分离富集介质,其高比表面积、高孔隙率性能赋予了它极高的吸附负载量,这些性能使得目标分析物可被高效富集;通过控制有机单体的链段长度、几何结构、掺杂元素、取代基团等方面精确调控I-COFs的孔洞结构和功能化基团,从而实现目标痕量物质的选择性富集。目前,I-COFs材料在样品前处理领域作为新型萃取介质已引起了极大关注。该文综述了近年来I-COFs材料的主要类型、合成方法及其在固相萃取、磁性固相萃取、分散固相萃取和固相微萃取方面的研究进展,同时展望了I-COFs在样品前处理领域的发展前景。

关键词: 亚胺类, 共价有机骨架, 样品前处理, 综述

Abstract:

Imine covalent organic frameworks (I-COFs), including imine-linked COFs and hydrazone-linked COFs, are a new type of crystalline porous organic materials constructed by the condensation of organic monomers by the Schiff-base reaction. Because they are composed of lightweight elements linked by strong covalent bonds, I-COF materials possess the advantages of low skeleton density, large surface area, high porosity, abundant monomer species, controllable pore size, functionalized structure, diverse synthetic methods, excellent adsorption performance, outstanding physical and chemical stabilities, etc. In recent years, interest in the field of I-COFs has increased tremendously because of their exceptional performance and broad applications in gas storage, gas separation, catalysis, sensing, photoelectric materials, sample pretreatment, drug delivery, and other fields. To date, imine bonds are one of the most widely used covalent bonds in COFs, and represent one of the most important ways to obtain I-COFs with excellent chemical stabilities. The synthesis methods for I-COFs include solvothermal synthesis, microwave synthesis, mechanochemical grinding synthesis, and room-temperature synthesis methods. Solvothermal synthesis is the most extensively used method for the production of I-COFs with high specific surface areas and good thermal stabilities. The microwave synthesis method is conducive to the rapid synthesis of COFs in industry, providing a more time-saving, simpler, and safer route for large-scale preparation of I-COFs. The mechanochemical grinding synthesis of porous solids has gained importance as an alternative to conventional solvothermal synthesis, because the process is quick, environment-friendly, and potentially scalable. The room-temperature method is characterized by mild reaction conditions and rapid reactions. It is an energy-saving, economic, safe, and green synthesis method, which has emerged as a hot spot in the preparation of I-COFs in recent years. Research progress over the past years on the application of I-COFs in the field of materials science has undoubtedly established the basis of its application in analytical chemistry. Owing to the excellent physical and chemical properties of I-COF materials, they are suitable for use as separation and enrichment media for trace target compounds in complex samples. The high specific surface area and porosity, extended conjugate network skeleton, and π-electron-rich nature of the materials endow it with a high adsorption capacity. These materials are highly enriched in target analytes by π-π interactions, acid-base interactions, donor-acceptor interactions, hydrogen bonding, hydrophobic interactions, and other intermolecular interactions. Precise control of the microporous structure of I-COFs was obtained by controlling the chain length, geometric structure, doping elements, and substituent groups of the organic monomers. Selective enrichment of target trace substances was achieved by modifying the groups of I-COFs based on the principle of host guest adaptation, molecular sieving, or microporous filling effect. At present, research on the synthesis of I-COF materials is in the stage of rapid development, and many I-COFs with excellent properties and great application potential have been synthesized, allowing widespread application of I-COFs in sample pretreatment medium. This review summarizes the current state-of-the-art on the main types and synthetic methods of I-COFs, as well as the applications of I-COFs in solid-phase extraction, magnetic solid-phase extraction, dispersive solid-phase extraction, and solid-phase microextraction. The prospects of I-COFs in sample pretreatment are also presented.

Key words: imine, covalent organic frameworks, sample pretreatment, review

中图分类号:

O658

袁红梅, 卢泽毅, 李玉凰, 张成江, 李攻科. 亚胺类共价有机骨架材料在样品前处理中的应用[J]. 色谱, 2022, 40(2): 109-122.

YUAN Hongmei, LU Zeyi, LI Yuhuang, ZHANG Chengjiang, LI Gongke. Application of imine covalent organic frameworks in sample pretreatment[J]. Chinese Journal of Chromatography, 2022, 40(2): 109-122.

图/表 3

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Extraction technology	I-COFs	Detection technology	Sample matrix		Analytical substance		Enrichment factors		Repeated times		LODs	Ref.
SPE	DAAQ-Tp	HPLC-UV	environmental water, food		BUs		-		30		0.02-0.05 ng/mL, 0.02-0.08 ng/g	[40]
	MICOFs	HPLC-DAD	plants		cyano pyrethroids		-		50		0.011-0.018 ng/g	[47]
	NH₂@COF	HPLC-DAD		environmental water		carboxylic acid pesticides		-		50	0.010-0.060 ng/mL	[52]
	COF@PS-GMA	UHPLC-UV		wastewater		NSAIDs		-		20	0.13-0.82 μg/L	[53]
	HL-COP	HPLC-UV		food		sudan dyes		305-757		-	0.03-0.15 μg/L	[54]
	CTpBD	ICP-MS		environmental water, food		metal ions		10		20	2.1-21.6 ng/L	[55]
MSPE	Fe₃O₄@TpPa-1	HPLC-FLD		environmental samples		PAHs		-		-	0.24-1.01 ng/L	[43]
	Fe₃O₄@COF	HPLC-Q-TOF/MS		human serum		peptides		-		10	-	[44]
	TAPB-Dha@Fe₃O₄	LC-MS/MS		fatty milk		OPPs		50		6	0.001-0.010 μg/L	[46]
	Fe₃O₄@COF@Zr⁴⁺	GC-FPD		vegetables		OPPs		-		6	0.7-3.0 μg/kg	[57]
	COF-(TpBD)/Fe₃O₄	GC-MS/MS		beverage		PAEs		-		4	0.005-2.748 μg/L	[58]
	Fe₃O₄@TpPa-1	Nano LC-MS/MS		human serum digests		N-glycopeptides		-		5	28 fmol	[60]
DSPE	CX4-BD-1, CX4-BD-2	UV-vis		environmental water		cationic dyes		-		-	-	[20]
	TAPB-TFA-COF	HPLC-DAD		environmental water		NACs		-		9	0.03-0.09 mg/L	[49]
	COF-LZU8	ICP-OES		water		Hg²⁺		-		3	25.0 μg/L	[62]
	[N] [COF-S]	XPS		seawater		uranium ions		-		6	-	[64]
	IBAs-AuNPs/COF	MALDI-TOF-MS		human serum		insulin		-		-	0.28 μg/L	[65]
	TpPa-2-Ti⁴⁺	LC-MS/MS		tryptic digests		phosphopeptides		-		-	4 fmol	[66]
SPME	TFPB-BD	GC-MS		aquatic products		PCBs		4471-7488		180	0.07-0.35 ng/L	[50]
	COF-SCU1	GC-MS/MS		indoor air		benzene homo- logues		276-887		100	0.03-0.15 ng/L	[68]
	OH-TPB-COF	GC-FID		environmental water		PAEs		-		60	0.032-0.451 μg/L	[69]
	Hydrazone COF	GC-ECD		vegetables, fruits		pyrethroids		307-2327		150	0.11-0.23 μg/kg	[70]
	TpBD	GC-MS/MS		grilled meat		PAHs		1069-10879		200	0.02-1.66 ng/L	[72]
	DAAQ-Tp	GC-FID		food packagings		BPA		-		-	3 μg/L	[73]

Extraction technology	I-COFs	Detection technology	Sample matrix		Analytical substance		Enrichment factors		Repeated times		LODs	Ref.
SPE	DAAQ-Tp	HPLC-UV	environmental water, food		BUs		-		30		0.02-0.05 ng/mL, 0.02-0.08 ng/g	[40]
	MICOFs	HPLC-DAD	plants		cyano pyrethroids		-		50		0.011-0.018 ng/g	[47]
	NH₂@COF	HPLC-DAD		environmental water		carboxylic acid pesticides		-		50	0.010-0.060 ng/mL	[52]
	COF@PS-GMA	UHPLC-UV		wastewater		NSAIDs		-		20	0.13-0.82 μg/L	[53]
	HL-COP	HPLC-UV		food		sudan dyes		305-757		-	0.03-0.15 μg/L	[54]
	CTpBD	ICP-MS		environmental water, food		metal ions		10		20	2.1-21.6 ng/L	[55]
MSPE	Fe₃O₄@TpPa-1	HPLC-FLD		environmental samples		PAHs		-		-	0.24-1.01 ng/L	[43]
	Fe₃O₄@COF	HPLC-Q-TOF/MS		human serum		peptides		-		10	-	[44]
	TAPB-Dha@Fe₃O₄	LC-MS/MS		fatty milk		OPPs		50		6	0.001-0.010 μg/L	[46]
	Fe₃O₄@COF@Zr⁴⁺	GC-FPD		vegetables		OPPs		-		6	0.7-3.0 μg/kg	[57]
	COF-(TpBD)/Fe₃O₄	GC-MS/MS		beverage		PAEs		-		4	0.005-2.748 μg/L	[58]
	Fe₃O₄@TpPa-1	Nano LC-MS/MS		human serum digests		N-glycopeptides		-		5	28 fmol	[60]
DSPE	CX4-BD-1, CX4-BD-2	UV-vis		environmental water		cationic dyes		-		-	-	[20]
	TAPB-TFA-COF	HPLC-DAD		environmental water		NACs		-		9	0.03-0.09 mg/L	[49]
	COF-LZU8	ICP-OES		water		Hg²⁺		-		3	25.0 μg/L	[62]
	[N] [COF-S]	XPS		seawater		uranium ions		-		6	-	[64]
	IBAs-AuNPs/COF	MALDI-TOF-MS		human serum		insulin		-		-	0.28 μg/L	[65]
	TpPa-2-Ti⁴⁺	LC-MS/MS		tryptic digests		phosphopeptides		-		-	4 fmol	[66]
SPME	TFPB-BD	GC-MS		aquatic products		PCBs		4471-7488		180	0.07-0.35 ng/L	[50]
	COF-SCU1	GC-MS/MS		indoor air		benzene homo- logues		276-887		100	0.03-0.15 ng/L	[68]
	OH-TPB-COF	GC-FID		environmental water		PAEs		-		60	0.032-0.451 μg/L	[69]
	Hydrazone COF	GC-ECD		vegetables, fruits		pyrethroids		307-2327		150	0.11-0.23 μg/kg	[70]
	TpBD	GC-MS/MS		grilled meat		PAHs		1069-10879		200	0.02-1.66 ng/L	[72]
	DAAQ-Tp	GC-FID		food packagings		BPA		-		-	3 μg/L	[73]