Research advances of porous organic framework materials on enrichment and detection of mycotoxins

doi:10.3724/SP.J.1123.2023.08003

Abstract

Abstract:

Mycotoxins are a class of toxic secondary metabolites produced by fungi. These substances are carcinogenic, teratogenic, and mutagenic, and cause serious harm to the human body; thus, they have attracted wide attention worldwide. Establishing accurate, rapid, and sensitive methods for the detection of mycotoxins is of great significance. Chromatography is a commonly used technology for mycotoxin detection. However, it is challenging to use in the direct analysis of these metabolites because of the wide variety and distribution of mycotoxins, their complex sample matrix, and their very low content in actual samples. Therefore, the development of suitable sample pretreatment methods for the efficient separation and enrichment of mycotoxins is necessary. In recent years, porous organic framework materials, which are represented by metal-organic frameworks (MOFs) and covalent-organic frameworks (COFs), have been widely applied in the sample pretreatment of mycotoxins owing to their many advantages, which include a large specific surface area, high porosity, adjustable pore size, diverse frame structures, uniform active site distribution, and modifiable structures. In addition, MOF/COF materials feature excellent fluorescence and electrochemical properties, rendering them highly suitable for mycotoxin analysis and sensing. In this article, the recent applications of MOF/COF materials in conventional sample pretreatment methods (e. g., solid-phase extraction, dispersive solid-phase extraction, magnetic solid-phase extraction, and immunomagnetic bead separation) for mycotoxin separation and enrichment are reviewed. Research on the use of MOF/COF materials for the fluorescence and electrochemical sensing of mycotoxins is also summarized. Finally, the existing challenges and future development trends of these materials are discussed and prospected to provide a reference for future research on the applications of MOF/COF materials in mycotoxin detection and analysis.

Key words: metal-organic framework (MOF), covalent-organic framework (COF), mycotoxins, enrichment, detection

CLC Number:

O658

LIU Wei, XU Zhiwei, WANG Rui, ZHAO Yu, JIA Qiong. Research advances of porous organic framework materials on enrichment and detection of mycotoxins[J]. Chinese Journal of Chromatography, 2023, 41(10): 891-900.

Figures/Tables 7

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Preparation method	Advantages	Disadvantages	Ref.
Water/solvent thermal synthesis	high purity, high crystallinity, regular shape	requirement of high temperature or high pressure	[20-30]
Room temperature agitation synthesis	simple operation, fast synthesis, high crystallisation rate and yields	poor crystallinity	[31-35]
Ultrasonic synthesis	simple equipment, fast reaction speed, low energy consumption	poor purity	[36]

Preparation method	Advantages	Disadvantages	Ref.
Water/solvent thermal synthesis	high purity, high crystallinity, regular shape	requirement of high temperature or high pressure	[20-30]
Room temperature agitation synthesis	simple operation, fast synthesis, high crystallisation rate and yields	poor crystallinity	[31-35]
Ultrasonic synthesis	simple equipment, fast reaction speed, low energy consumption	poor purity	[36]

Sensor	Detection method	Analyte	Real samples	LOD/(ng/L)	Ref.
NH₂-MIL-53(Al)	fluorescence sensing	AFB₁	tea	1.167×10⁴	[33]
COFs TpBD	electrochemical sensing	AFB₁	milk	150	[36]
Mn²⁺@UIO-66(Zr)-(COOH)₂	electrochemical sensing	OTA	corn, orange juice	0.289	[58]
AuNPs@Cd-MOF-74	electrochemical sensing	OTA	red wine	10	[59]
Co/NCNT-Ab₂	colorimetric-fluorescence	OTA	corn, millet	0.21	[60]
	dual-mode sensing			0.17
UiO-66	electrochemical sensing	OTA	red wine	7.9×10^-11*	[61]
Dpy-NhBt-COF@Tb³⁺	fluorescence sensing	OTA	wheat	1.35×10^-2*	[62]
COF-Au-MB-Apt	electrochemical sensing	OTA	-	0.12	[63]
Co/Fe-MOFs	electrochemical sensing	OTA	-	3.0×10^-4	[64]
Ag NPs@ZnMOF@MIP	fluorescence sensing	PAT	environmental water, apple juice	0.06^*	[23]
MIP/Au@PANI/SeS₂@Co MOF	electrochemical sensing	PAT	apple juice	6.6×10^-7*	[27]
Zr-MOFmix	fluorescence sensing	PAT	apple juice	0.871	[65]
Pt@AuNRs/Fe-MOFs/PEIrGO	electrochemical sensing	PAT	apple juice, apple wine	4.14×10^-2	[66]
AuNPs@Ce-TpBpy COF	electrochemical sensing	ZEN	cornflour	0.389	[67]
ZrMOF@MPDB	fluorescence sensing	3-NPA	sugarcane juice	15^*	[26]
Zn-CoMOF/Ti₃C₂ MXene/Fe₃O₄-MGO	electrochemical sensing	MPA	grass silages	2.1×10^-2*	[32]
Hemin@UiO-66-NH₂	electrochemical sensing	FB₁	maize	24	[34]

Sensor	Detection method	Analyte	Real samples	LOD/(ng/L)	Ref.
NH₂-MIL-53(Al)	fluorescence sensing	AFB₁	tea	1.167×10⁴	[33]
COFs TpBD	electrochemical sensing	AFB₁	milk	150	[36]
Mn²⁺@UIO-66(Zr)-(COOH)₂	electrochemical sensing	OTA	corn, orange juice	0.289	[58]
AuNPs@Cd-MOF-74	electrochemical sensing	OTA	red wine	10	[59]
Co/NCNT-Ab₂	colorimetric-fluorescence	OTA	corn, millet	0.21	[60]
	dual-mode sensing			0.17
UiO-66	electrochemical sensing	OTA	red wine	7.9×10^-11*	[61]
Dpy-NhBt-COF@Tb³⁺	fluorescence sensing	OTA	wheat	1.35×10^-2*	[62]
COF-Au-MB-Apt	electrochemical sensing	OTA	-	0.12	[63]
Co/Fe-MOFs	electrochemical sensing	OTA	-	3.0×10^-4	[64]
Ag NPs@ZnMOF@MIP	fluorescence sensing	PAT	environmental water, apple juice	0.06^*	[23]
MIP/Au@PANI/SeS₂@Co MOF	electrochemical sensing	PAT	apple juice	6.6×10^-7*	[27]
Zr-MOFmix	fluorescence sensing	PAT	apple juice	0.871	[65]
Pt@AuNRs/Fe-MOFs/PEIrGO	electrochemical sensing	PAT	apple juice, apple wine	4.14×10^-2	[66]
AuNPs@Ce-TpBpy COF	electrochemical sensing	ZEN	cornflour	0.389	[67]
ZrMOF@MPDB	fluorescence sensing	3-NPA	sugarcane juice	15^*	[26]
Zn-CoMOF/Ti₃C₂ MXene/Fe₃O₄-MGO	electrochemical sensing	MPA	grass silages	2.1×10^-2*	[32]
Hemin@UiO-66-NH₂	electrochemical sensing	FB₁	maize	24	[34]