干果类食品的样品前处理与分析检测方法研究进展

doi:10.3724/SP.J.1123.2021.06030

摘要/Abstract

摘要：

坚果、果脯等干果类食品含有丰富的营养成分,深受国内外广大消费者的喜爱。但这些食品在果实生产、加工、储运时会使用农药或产生霉变等,造成干果中农药、重金属、霉菌毒素或添加剂等有害成分残留,甚至超过国家限量要求,带来严重的食品安全问题。因此,加强干果类食品的质量监督具有重要的经济和社会意义。但干果类食品基质复杂,有害物质种类多,结构和性质差异大,含量低,其分析检测需要快速高效的样品前处理技术和准确灵敏的分析检测方法。该文主要综述了近十年来干果类食品中有害物质的样品前处理及分析检测方法研究进展。其中样品前处理方法主要包括各种场辅助萃取法、相分离法和衍生化萃取方法等。场辅助萃取法主要是借助超声波和微波场等外场(协同)作用加快干果中有害物质的溶出速度,提高其萃取效率。相分离法,包括固相(微)萃取、分散固相萃取和液相(微)萃取法等,具有溶剂消耗少、分离富集效率高的优势,是干果样品分析中较常使用的前处理方法。该文还重点介绍了干果中各类有害成分分析检测技术,主要包括色谱、原子光谱、无机质谱、电化学分析等常规实验室方法,以及一些适用于现场分析的快速检测技术,并以此为基础,展望了干果类食品中有害物质分析检测技术的发展趋势。

关键词: 样品前处理, 分析检测方法, 食品安全, 有害物质, 干果, 综述

Abstract:

Dried fruit foods, including nuts and preserved fruits, are favored by consumers and are rich in protein, lipids, minerals, vitamins, and other nutrients. However, these food products can be contaminated by pesticide residues, heavy metals, mycotoxins, and additives during growth, processing, storage, and transportation. The presence of such pollutants in excess of a certain limit will lead to food safety problems. Therefore, it is of great economic and social significance to strengthen the quality supervision of dried fruit foods. However, these foods have a complex matrix and low concentrations of various harmful substances, which necessitates efficient and appropriate sample preparation methods as well as rapid, accurate detection methods. In the present article, the sample preparation and analytical methods for harmful substances in dried fruit foods since 2010 are reviewed. The sample preparation methods are classified as field-assisted extraction, phase separation, and derivatization and extraction methods. The field-assisted extraction method is based on the action of an external field (synergistic) such as ultrasonic or microwave fields to increase the dissolution rate of hazardous substances in dried fruits and improve the extraction efficiency. Phase separation methods such as solid-phase extraction, dispersive solid-phase extraction and solid-phase microextraction are commonly used as sample preparation methods for dried fruit samples, because of the advantages of low solvent consumption and wide analysis range. Moreover, this paper discusses the progress of various analytical methods for these hazardous substances in dried fruits, including conventional laboratory methods such as chromatography, atomic spectroscopy, inorganic mass spectrometry, and electrochemical analysis, as well as rapid detection techniques suitable for field analysis. Laboratory testing has the advantages of high accuracy, high sensitivity, and low detection limits. However, it has the disadvantages of complicated preparation, long analysis time, and difficult operation. Rapid detection technology speeds up the analytical speed, has operational simplicity, and saves analysis time. The complexity of the food matrix, which easily interferes with the sample matrix, low selectivity, and difficulty in accurate quantification, it is necessary to minimize cases of incorrect or erroneous detection. Therefore, rapid detection of harmful substances in dried fruit foods is possible by optimizing the sample pretreatment methods and detection technologies, and by seeking new (especially, on-site) detection technologies. Prospects on the development of selective and non-destructive sample preparation methods and automated, high-throughput, rapid detection methods in dried fruit food analysis are presented. The development of new, green rapid sample pretreatment methods and technical products that integrate separation, enrichment, and detection as well as the construction of accurate and sensitive rapid detection methods are expected to become the development trend in the analysis of harmful substances in dried fruit foods.

Key words: sample preparation, analytical methods, food safety, hazardous substances, dried fruit foods, review

中图分类号:

O658

周丽慧, 肖小华, 李攻科. 干果类食品的样品前处理与分析检测方法研究进展[J]. 色谱, 2021, 39(9): 958-967.

ZHOU Lihui, XIAO Xiaohua, LI Gongke. Progress of sample preparation and analytical methods of dried fruit foods[J]. Chinese Journal of Chromatography, 2021, 39(9): 958-967.

图/表 5

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Hazardous substances	Category	Analytes	Maximum residue limit/ (mg/kg)		Maximum usage/ (g/kg)		Sample preparation methods	Analytical methods	Ref.
Pesticide	insecticide	pyrethroids, organic phosphines	0.01-	6	-		UAE, MAE,	GC, GC-MS,	[30-34]
residue	bactericide	dithiocarbamates, triazoles	0.01-	60	-		SPE, DSPE,	HPLC-MS/MS,
	herbicide	paraquat, aquacide, glufosinate ammonium	0.01-	0.3	-		QuEChERS	HPLC
	plant growth regulator	gibberellin, forchlorfenuron, bentazone, zearalenone, 2,4-dichlorophenoxyacetic acid	0.2-	10	-
Heavy metal	heavy metal	Pb, Hg, Cd, Cr, As	-		-		Microwave- digestion, UAE	AAS, AFS, ICP- OES, ICP-MS	[35]
Fungimycin	fungimycin	aflatoxin	5.0-	50^*	-		SPE, SPME, DSPE, QuEChERS, LLME	HPLC, HPLC-MS, ELISA, FL, ECL	[36-38]
Food additives	sweetening agent	aspartame, saccharin sodium, cyclamate	-		0.025-	6.0	UAE, SPE, derivatization,	IC, HPLC, HPLC- MS, UV-Vis	[39,40]
	preservative	nitrite	-		0.5-	1.0	DLLME	GC, HPLC, UV-Vis,	[16,39,41]
	decolorant	sulfur dioxide, sulfur	-		0.05-	0.35		ELISA, SERS, IC, SWSV
	colorant	sudan red, rose red B, acid orange Ⅱ	-		0.1-	10		CE, ICP-MS, HPLC, SERS	[39,42,43]
Allergen	allergenic protein	Cora 1, Cora 8, Arah 1	-		-		UAE	ELISA, PCR, HPLC-MS/MS	[44,45]

Hazardous substances	Category	Analytes	Maximum residue limit/ (mg/kg)		Maximum usage/ (g/kg)		Sample preparation methods	Analytical methods	Ref.
Pesticide	insecticide	pyrethroids, organic phosphines	0.01-	6	-		UAE, MAE,	GC, GC-MS,	[30-34]
residue	bactericide	dithiocarbamates, triazoles	0.01-	60	-		SPE, DSPE,	HPLC-MS/MS,
	herbicide	paraquat, aquacide, glufosinate ammonium	0.01-	0.3	-		QuEChERS	HPLC
	plant growth regulator	gibberellin, forchlorfenuron, bentazone, zearalenone, 2,4-dichlorophenoxyacetic acid	0.2-	10	-
Heavy metal	heavy metal	Pb, Hg, Cd, Cr, As	-		-		Microwave- digestion, UAE	AAS, AFS, ICP- OES, ICP-MS	[35]
Fungimycin	fungimycin	aflatoxin	5.0-	50^*	-		SPE, SPME, DSPE, QuEChERS, LLME	HPLC, HPLC-MS, ELISA, FL, ECL	[36-38]
Food additives	sweetening agent	aspartame, saccharin sodium, cyclamate	-		0.025-	6.0	UAE, SPE, derivatization,	IC, HPLC, HPLC- MS, UV-Vis	[39,40]
	preservative	nitrite	-		0.5-	1.0	DLLME	GC, HPLC, UV-Vis,	[16,39,41]
	decolorant	sulfur dioxide, sulfur	-		0.05-	0.35		ELISA, SERS, IC, SWSV
	colorant	sudan red, rose red B, acid orange Ⅱ	-		0.1-	10		CE, ICP-MS, HPLC, SERS	[39,42,43]
Allergen	allergenic protein	Cora 1, Cora 8, Arah 1	-		-		UAE	ELISA, PCR, HPLC-MS/MS	[44,45]

Sample preparation methods	Advantages	Disadvantages	Ref.
UAE, MAE	high extraction efficiency, fast speed,	filtration, operation trouble	[46,47]
	low cost, low solvent consumption
SPE	low solvent consumption, no separation operation, small volume samples	long extraction time, poor batch repeatability	[48]
SPME	combination of extraction and concentration, time-consuming, few organic solvent	fragile fiber, peeling of coating, memory effect	[49]
DSPE	simple and fast operation, low cost, wide analysis range	cumbersome process, matrix effects, low-throughput analysis	[50]
LLME DLLME	high extraction efficiency, environmentally friendly	centrifugal separation, poor recovery	[51] [52]
Derivatization	improvements in the detectability of analytes and separation effect	cumbersome operation, effects on chromatographic separation and quantitative accuracy	[53]

Sample preparation methods	Advantages	Disadvantages	Ref.
UAE, MAE	high extraction efficiency, fast speed,	filtration, operation trouble	[46,47]
	low cost, low solvent consumption
SPE	low solvent consumption, no separation operation, small volume samples	long extraction time, poor batch repeatability	[48]
SPME	combination of extraction and concentration, time-consuming, few organic solvent	fragile fiber, peeling of coating, memory effect	[49]
DSPE	simple and fast operation, low cost, wide analysis range	cumbersome process, matrix effects, low-throughput analysis	[50]
LLME DLLME	high extraction efficiency, environmentally friendly	centrifugal separation, poor recovery	[51] [52]
Derivatization	improvements in the detectability of analytes and separation effect	cumbersome operation, effects on chromatographic separation and quantitative accuracy	[53]

Analytical method	Analytes	Samples	LOD/(μg/kg)	Recovery/%		Ref.
SPME-LC/MS	patulin	dried fruit	0.0235^*	92.5-	94.5	[91]
QuEChERS-UPLC-MS/MS	pesticide residue	nut	0.01-10	51.0-	126.0	[92]
HPLC	food additives	preserved fruit	100-250	90.2-	106.3	[93]
QuEChERS-GC-MS/MS	multi-residue pesticide	dried fruits	-	70-	120	[94]
QuEChERS-LC-ESI-MS	acrylamide	dried fruits	2.0	61-	82	[95]
DSPE-CE	synthetic food colorants	preserved fruit	3.50-5.50	94.3-	102	[62]
IC	sulfites	dried fruits	143^*	81-	105	[82]
AFS	mercury	nuts	0.08	100-	101	[83]
ICP-MS	heavy metal	dried strawberry	2.60-427.60	79-	104.9	[85]