新型纳米材料在农产品安全分析中的应用进展

doi:10.3724/SP.J.1123.2022.09010

摘要/Abstract

摘要：

农产品质量安全事关民生福祉,近年来受到了政府和消费者越来越多的关注,建立农产品中农药、兽药、重金属和真菌毒素等污染物高效、快速和灵敏的分离分析新方法,对于保障农产品质量安全具有重要的意义。农产品基质复杂,污染物浓度低,采取适当的样品前处理对农产品中的污染物进行富集净化是非常重要的。固相萃取是目前应用最多的样品前处理技术,其核心吸附剂决定了萃取的选择性和萃取效率。近年来,越来越多的新型材料被用作固相萃取的吸附剂,结合多种萃取模式(固相微萃取、分散固相萃取、磁性固相萃取等),大大提高了目标物的萃取效率、萃取选择性和分析通量。纳米材料具有大的比表面积,对痕量目标物亲和力强,将其作为固相萃取的吸附剂,极大地改善了分析技术的选择性和灵敏度,已经成为农产品中痕量化合物预富集技术的优先选择。本文概述了磁性材料、碳基材料、金属和金属氧化物材料、金属有机骨架材料、有机共价骨架材料等纳米材料的吸附特性,因具有比表面积大、吸附容量高、结构可设计等众多优点,良好的稳定性和优异的物理化学性能使其非常适合作为农产品安全分析中污染物富集净化的吸附剂,结合色谱、光谱、质谱等检测技术,所开发的分析方法成功应用于多种农产品中污染物的分析,很好地消除了基质干扰,提高了样品前处理的萃取效率、选择性和分析通量。本文围绕几类新型纳米分离材料在农产品质量安全分析中的应用进行了综述,重点阐述了吸附剂与目标物的作用机理,并对其进一步的开发和应用进行了展望,以期为新型纳米分离介质的制备及其在农产品安全分析中的应用提供参考。

关键词: 新型纳米材料, 农产品质量安全, 样品制备, 综述

Abstract:

The quality and safety of agricultural products are strongly related to human livelihood. Thus, the government and consumers have recently paid increased attention to the quality and safety of agricultural products. The development of efficient, rapid, and sensitive analytical methods for detecting pesticides, veterinary drugs, heavy metals, mycotoxins, and environmental pollutants in agricultural products is of great significance. Owing to the complexity of many sample matrices and the low concentration of pollutants in a typical sample, appropriate sample pretreatment steps are necessary to enrich pollutants in agricultural products. Solid-phase extraction (SPE) is the most widely used sample pretreatment technology; in this technique, the adsorbent generally determines the selectivity and efficiency of the extraction process. An increasing number of novel materials have been used as SPE adsorbents. The extraction efficiency, extraction selectivity, and analytical throughput of SPE could be greatly improved by combining these novel materials with various extraction modes (e. g., solid-phase microextraction, dispersed SPE, and magnetic SPE (MSPE)) during sample preparation. Because of their large specific surface area and high affinity toward target analytes, nanomaterials are often used as SPE adsorbents, thereby greatly improving the selectivity and sensitivity of the analytical technology. More importantly, these materials have become a priority area of research on preconcentration technologies for trace compounds in agricultural products. This paper summarizes the adsorption characteristics of several new nanomaterials, including magnetic materials, carbon-based materials, metal nanomaterials (MNs), metal oxide nanomaterials (MONs), metal organic frameworks (MOFs), and covalent organic frameworks (COFs). These nanomaterials present numerous advantages, such as large specific surface areas, high adsorption capacities, and tailorable structural designs. MSPE employs magnetic materials as sorbents to afford fast dispersion and efficient recycling when applied to complex sample matrices under an external magnetic field. The use of MSPE can avoid several typical problems associated with SPE such as poor adsorbent packing and high pressure, thereby greatly simplifying the pretreatment process and providing a high flux for sample analysis. Carbon-based materials are powdered or bulk nonmetallic solid materials with carbon as the main component; carbon and nitrogen materials, mesoporous carbon, carbon nanotubes, and graphene are some examples of these materials. These materials provide large specific surface areas, abundant pore structures, good thermal stability, high mechanical strength and adsorption capacity, and controllable morphology. Pure and modified carbon nanomaterials have been successfully used to purify target analytes from agricultural products. Given their unique physical and chemical properties, MNs and MONs have attracted significant interest for use in sample preparation. MNs and MONs with excellent thermal and mechanical stabilities show good resistance to a wide pH range and diverse organic solvents, which is crucial in adsorbent-based extraction methods. The surface of these materials can be easily modified with various ligands to improve their selectivity. MOFs and COFs present many advantages such as large specific surface areas, high porosity, adjustable pore performance, and good thermal stability. Several methods that employ novel adsorbent materials to analyze pollutants in a variety of agricultural products, such as chromatography, spectroscopy, mass spectrometry, and other detection technologies, have been established. This paper also reviews the application of adsorbent materials in the analysis of agricultural product quality and safety, and discusses the future development trends of these sorbents in sample preparation for the safety analysis of agricultural products.

Key words: novel nanomaterial, quality safety of agricultural products, sample preparation, review

中图分类号:

O658

周然锋, 张惠贤, 尹小丽, 彭西甜. 新型纳米材料在农产品安全分析中的应用进展[J]. 色谱, 2023, 41(9): 731-741.

ZHOU Ranfeng, ZHANG Huixian, YIN Xiaoli, PENG Xitian. Progress in the application of novel nano-materials to the safety analysis of agricultural products[J]. Chinese Journal of Chromatography, 2023, 41(9): 731-741.

图/表 6

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Nano-material	Analytes	Matrices	Detection method	Recoveries/ %		Adsorption mechanisms	LODs	Ref.
MNPCs	organophosphorus	fruit	GC-FPD	84.0	-116.0	π-π, hydrophobic	0.018-0.045 μg/L	[55]
MWCNTs	procymidone, atrazine, methidathion, etc.	cabbage apple and orange	GC-MS/MS	75.3	-113.6	π-π, hydrophobic	0.1-2.6 μg/kg	[56]
Magnetic porous carbon	methomyl, isoprocarb, carbofuran, etc.	honey	LC-MS/MS	61.6	-112	π-π, hydrophobic	0.5-25 μg/kg	[57]
AAS/NZVI/GO	methomyl, carbaryl, isoprocarb, etc.	sewage	LC-MS	93.4	-97.2	π-π, hydrophobic, electrostatic interaction	-	[58]
TP-MWCNTs	organophosphorus	vegetables	GC-MS	73.5	-114.2	π-π, hydrophobic interaction	0.81-7.63 μg/kg	[59]

Nano-material	Analytes	Matrices	Detection method	Recoveries/ %		Adsorption mechanisms	LODs	Ref.
MNPCs	organophosphorus	fruit	GC-FPD	84.0	-116.0	π-π, hydrophobic	0.018-0.045 μg/L	[55]
MWCNTs	procymidone, atrazine, methidathion, etc.	cabbage apple and orange	GC-MS/MS	75.3	-113.6	π-π, hydrophobic	0.1-2.6 μg/kg	[56]
Magnetic porous carbon	methomyl, isoprocarb, carbofuran, etc.	honey	LC-MS/MS	61.6	-112	π-π, hydrophobic	0.5-25 μg/kg	[57]
AAS/NZVI/GO	methomyl, carbaryl, isoprocarb, etc.	sewage	LC-MS	93.4	-97.2	π-π, hydrophobic, electrostatic interaction	-	[58]
TP-MWCNTs	organophosphorus	vegetables	GC-MS	73.5	-114.2	π-π, hydrophobic interaction	0.81-7.63 μg/kg	[59]

Nano-material	Analytes	Matrices	Detection method	Recoveries/ %		Adsorption mechanisms	LODs	Ref.
HP-Nu-902-X	sulfonamides	milk	HPLC-UV	73.8	-100.5	π-π, interaction	0.25 ng/mL	[65]
RAM-MMIPs	tetracyclines	egg	HPLC-UV	84.2	-96.5	electrostatic and hydrophobic interaction	2.21-2.67 μg/L	[66]
YS-Fe₃O₄@GC	sulfonamides	milk, meat	HPLC-UV	77.2	-118.0	π-π, electrostatic interaction	0.11-0.25 μg/L	[67]
Magnetic porous carbon	sulfonamides	milk	HPLC-DAD	76.9	-109.0	π-π, cation-π interaction, hydrogen bond	0.02-0.04 ng/mL	[68]
Fe₃O₄@CS-IL NPs	sulfonamides	milk	HPLC-MS/MS	85.9	-107.5	π-π, electrostatic interaction	0.04-0.19 μg/kg	[69]

Nano-material	Analytes	Matrices	Detection method	Recoveries/ %		Adsorption mechanisms	LODs	Ref.
HP-Nu-902-X	sulfonamides	milk	HPLC-UV	73.8	-100.5	π-π, interaction	0.25 ng/mL	[65]
RAM-MMIPs	tetracyclines	egg	HPLC-UV	84.2	-96.5	electrostatic and hydrophobic interaction	2.21-2.67 μg/L	[66]
YS-Fe₃O₄@GC	sulfonamides	milk, meat	HPLC-UV	77.2	-118.0	π-π, electrostatic interaction	0.11-0.25 μg/L	[67]
Magnetic porous carbon	sulfonamides	milk	HPLC-DAD	76.9	-109.0	π-π, cation-π interaction, hydrogen bond	0.02-0.04 ng/mL	[68]
Fe₃O₄@CS-IL NPs	sulfonamides	milk	HPLC-MS/MS	85.9	-107.5	π-π, electrostatic interaction	0.04-0.19 μg/kg	[69]

Nano-material	Analytes	Matrix	Detection method	Recoveries/ %		Adsorption mechanisms	LODs	Ref.
SAC-MNPs	Pb(Ⅱ)	red pepper	SQT-FAAS	102.6	-106.6	charge transfer	0.01-0.03 ng/mL	[74]
MMOF	Hg(Ⅱ)	shrimp	CVAAS	82.0	-112.0	electrostatic interaction	0.015 μg/kg	[75]
MnFe₂O₄-cellulose	Gd(Ⅱ)	lettuce	FAAS	95		charge transfer	0.5 μg/L	[76]
MWCNTs@MgAl₂O₄@TiO₂	Pb(Ⅱ)	garlic	FAAS	91.0	-100.0	electrostatic interaction	0.42 μg/L	[77]
Fe₃O₄-Ti₃AlC₂	Cd(Ⅱ), Co(Ⅱ)	food	FAAS	92.0	-101.0	electrostatic interaction	0.093l, 0.297 μg/L	[78]