微芯片电泳技术在生物样品分离分析中的研究进展

doi:10.3724/SP.J.1123.2022.12004

摘要/Abstract

摘要：

微芯片电泳技术是在微芯片中通过流体操控实现电泳分离的分析技术,具有分离效率高、样品量消耗少、分析速度快、易于集成等优势,已广泛应用于生物、医药等复杂样品的快速分离分析中。本文综述了微芯片电泳技术在微芯片材料、电泳模式、检测方式及生物样品分离分析等方面的研究进展。微芯片材料包括芯片材料与通道修饰方法以及电极材料与电极集成方式。芯片材料主要包括硅、玻璃、纸材料、聚二甲基硅氧烷和聚甲基丙烯酸甲酯等聚合物材料;通道修饰方法是指在微通道上的动、静修饰方法。电极材料与电极集成方式包括研制电极所需的金、铂、银材料以及将电极与微芯片集成的加工方式。根据施加电场是否均匀,微芯片电泳技术可分为均匀和非均匀电场两种电泳模式。均匀电场模式主要为微自由流电泳和微区带电泳,包括微等电聚焦电泳、微等速电泳、微密度梯度电泳等;非均匀电场模式主要为微介电泳。微芯片电泳技术通常与光谱、电化学和质谱等分析检测技术联用,实现复杂样品的快速、高效分离分析。近年来微芯片电泳在高通量和原位分离分析方面还发展了许多新模式和新策略。本文介绍了微芯片电泳技术在生物大分子、生物小分子、生物粒子等生物样品中的分离分析进展,并展望了微芯片电泳技术在生物样品分离分析中的发展趋势。

关键词: 微芯片电泳, 生物样品, 分离分析, 研究进展

Abstract:

Microchip electrophoresis is a separation technology that involves fluid manipulation in a microchip; the advantages of this technique include high separation efficiency, low sample consumption, and fast and easy multistep integration. Microchip electrophoresis has been widely used to rapidly separate and analyze complex samples in biology and medicine. In this paper, we review the research progress on microchip electrophoresis, explore the fabrication and separation modes of microchip materials, and discuss their applications in the detection and analysis of biological samples. Research on microchip materials can be mainly categorized into chip materials, channel modifications, electrode materials, and electrode integration methods. Microchip materials research involves the development of silicon, glass, polydimethylsiloxane and polymethyl methacrylate-based, and paper electrophoretic materials. Microchannel modification research primarily focuses on the dynamic and static modification methods of microchannels. Although chip materials and fabrication technologies have improved over the years, problems such as high manufacturing costs, long processing time, and short service lives continue to persist. These problems hinder the industrialization of microchip electrophoresis. At present, few static methods for the surface modification of polymer channels are available, and most of them involve a combination of physical adsorption and polymers. Therefore, developing efficient surface modification methods for polymer channels remains a necessary undertaking. In addition, both dynamic and static modifications require the introduction of other chemicals, which may not be conducive to the expansion of subsequent experiments. The materials commonly used in the development of electrodes and processing methods for electrode-microchip integration include gold, platinum, and silver. Microchip electrophoresis can be divided into two modes according to the uniformity of the electric field: uniform and non-uniform. The uniform electric field electrophoresis mode mainly involves micro free-flow electrophoresis and micro zone electrophoresis, including micro isoelectric focusing electrophoresis, micro isovelocity electrophoresis, and micro density gradient electrophoresis. The non-uniform electric field electrophoresis mode involves micro dielectric electrophoresis. Microchip electrophoresis is typically used in conjunction with conventional laboratory methods, such as optical, electrochemical, and mass spectrometry, to achieve the rapid and efficient separation and analysis of complex samples. However, the labeling required for most widely used laser-induced fluorescence technologies often involves a cumbersome organic synthesis process, and not all samples can be labeled, which limits the application scenarios of laser-induced fluorescence. The applications of unlabeled microchip electrophoresis-chemiluminescence/dielectrophoresis are also limited, and simplification of the experimental process to achieve simple and rapid microchip electrophoresis remains challenging. Several new models and strategies for high throughput in situ detection based on these detection methods have been developed for microchip electrophoretic systems. However, high throughput analysis by microchip electrophoresis is often dependent on complex chip structures and relatively complicated detection methods; thus, simple high throughput analytical technologies must be further explored. This paper also reviews the progress on microchip electrophoresis for the separation and analysis of complex biological samples, such as biomacromolecules, biological small molecules, and bioparticles, and forecasts the development trend of microchip electrophoresis in the separation and analysis of biomolecules. Over 250 research papers on this field are published annually, and it is gradually becoming a research focus. Most previous research has focused on biomacromolecules, including proteins and nucleic acids; biological small molecules, including amino acids, metabolites, and ions; and bioparticles, including cells and pathogens. However, several problems remain unsolved in the field of microchip electrophoresis. Overall, microchip electrophoresis requires further study to increase its suitability for the separation and analysis of complex biological samples.

Key words: microchip electrophoresis, biological samples, separation and analysis, research progress

中图分类号:

O658

黄剑英, 夏凌, 肖小华, 李攻科. 微芯片电泳技术在生物样品分离分析中的研究进展[J]. 色谱, 2023, 41(8): 641-650.

HUANG Jianying, XIA Ling, XIAO Xiaohua, LI Gongke. Advances in microchip electrophoresis for the separation and analysis of biological samples[J]. Chinese Journal of Chromatography, 2023, 41(8): 641-650.

图/表 6

参考文献

[1]	Keçili R, Hussain C M. Trends Environ Anal, 2021, 31: e128
[2]	Chen W W, Gan Z Q, Qin J H. Chinese Journal of Chromatography, 2021, 39(9): 968
[2]	陈雯雯, 甘忠桥, 秦建华. 色谱, 2021, 39(9): 968
[3]	Vitorino R, Guedes S, Da Costa J P, et al. Nanomaterials-Basel, 2021, 11(5): 1118
[4]	Wu F, Liang S, Zhuang N B, et al. Journal of Experimental Hematology, 2020, 28(5): 1733
[4]	吴凡, 梁爽, 庄乃保, 等. 中国实验血液学杂志, 2020, 28(5): 1733
[5]	Chen P, Chen D, Li S, et al. TrAC-Trends Anal Chem, 2019, 117: 2
[6]	Duarte L M, Moreira R C, Coltro W K T. Electrophoresis, 2020, 41(7/8): 434
[7]	Chen T Y, Wu J. Chinese Journal of Analysis Laboratory, 2021, 40(6): 621
[7]	陈天友, 吴静. 分析试验室, 2021, 40(6): 621
[8]	Kasicka V. Electrophoresis, 2022, 43(1/2): 82
[9]	Costa B M D C, Griveau S, D'Orlye F, et al. Electrochim Acta, 2021, 391: 138928
[10]	Ding F F, Zhu Y, Guo R, et al. Chinese Journal of Chromatography, 2019, 37(2): 132
[10]	丁芳芳, 朱珏, 郭睿, 等. 色谱, 2019, 37(2): 132
[11]	Beauchamp M J, Nielsen A V, Gong H, et al. Anal Chem, 2019, 91(11): 7418
[12]	Esene J E, Boaks M, Bickham A V, et al. Microchim Acta, 2022, 189(5): 2045
[13]	Costa B M C, Coelho A G, Beauchamp M J, et al. Anal Bioanal Chem, 2022, 414(1): 545
[14]	Castiaux A D, Selemani M A, Ward M A, et al. Anal Methods-UK, 2021, 13(42): 5017
[15]	Wang C, Zhang Q, Liu X, et al. Lab Chip, 2019, 19(3): 484
[16]	Han X, Zhang Y, Tian J, et al. Polym Eng Sci, 2022, 62(1): 3
[17]	Lobo Júnior E O, Chagas C L S, Duarte L C, et al. Electrophoresis, 2020, 41(18/19): 1641
[18]	Azouz A B, Murphy S, Karazi S, et al. Mater Manuf Process, 2014, 29(2): 93
[19]	Liu H, Liu M M, Yang Y J, et al. Chinese Journal of Analytical Chemistry, 2021, 49(11): 1937
[19]	刘辉, 刘萌萌, 杨元杰, 等. 分析化学, 2021, 49(11): 1937
[20]	Quero R F, Costa B M D C, Da Silva J A F, et al. Sensor Actuat B-Chem, 2022, 365: 131959
[21]	Beauchamp M J, Nielsen A V, Gong H, et al. Anal Chem, 2019, 91(11): 7418
[22]	Walczak R, Adamski K, Kubicki W. Sensor Actuat B-Chem, 2018, 261: 474
[23]	Zhang Y, Qi J, Liu F, et al. Chinese Journal of Chromatography, 2021, 39(8): 802
[23]	张昱, 齐骥, 刘丰, 等. 色谱, 2021, 39(8): 802
[24]	Arantes I V S, Paixão T R L C. Talanta, 2022, 240: 123201
[25]	Liu Y, Xia L, Xiao X, et al. Electrophoresis, 2022, 43(7/8): 892
[26]	Bernardo-Bermejo S, Sánchez-López E, Castro-Puyana M, et al. TrAC-Trends Anal Chem, 2020, 124: 115807
[27]	Sun L, Luo Y, Gao Z, et al. Electrophoresis, 2015, 36(6): 889
[28]	Song Y, Feng A, Liu Z, et al. Electrophoresis, 2020, 41(10/11): 761
[29]	Chen Y, Xia L, Xiao X, et al. J Sep Sci, 2022, 45(12): 2045
[30]	Mohammadzadeh A, Fox Robichaud A E, Selvaganapathy P R. J Microelectromech S, 2019, 28(4): 597
[31]	Birch C, DuVall J, Le Roux D, et al. Micromachines-Basel, 2017, 8(1): 17
[32]	Wu Y Y, Yan P Y, Liu Y, et al. Journal of Taiyuan University of Technology, 2021, 52(6): 990
[32]	武月园, 燕鹏云, 刘洋, 等. 太原理工大学学报, 2021, 52(6): 990
[33]	Birch C, Landers J. Micromachines-Basel, 2017, 8(3): 76
[34]	Harrison D J, Manz A, Fan Z, et al. Anal Chem, 1992, 64(17): 1926
[35]	Tang T, Yuan Y P, Yalikun Y, et al. Sensor Actuators B-Chem, 2021, 339: 129859
[36]	Munteanu F, Titoiu A, Marty J, et al. Sensors-Basel, 2018, 18(3): 901
[37]	Petroni J M, Lucca B G, Ferreira V S. Anal Chim Acta, 2017, 954: 88
[38]	Liu Y, Li C, Li Z, et al. Electrophoresis, 2016, 37(3): 545
[39]	Shebindu A, Somaweera H, Estlack Z, et al. Talanta, 2021, 225: 122039
[40]	Cornejo M A, Linz T H. Anal Chem, 2022, 94(14): 5674
[41]	Peli Thanthri S H, Ward C L, Cornejo M A, et al. Anal Chem, 2020, 92(9): 6741
[42]	Zhang H, Chang H, Neuzil P. Micromachines-Basel, 2019, 10(6): 423
[43]	Varmazyari V, Habibiyan H, Ghafoorifard H, et al. Sci Rep-UK, 2022, 12(1): 121001
[44]	Song Y, Han X, Li D, et al. RSC Adv, 2021, 11(7): 3827
[45]	Wu F, Fan L, Zeng Y X, et al. Micronanoelectronic Technology, 2018, 55(2): 116
[45]	吴菲, 樊磊, 曾一笑, 等. 微纳电子技术, 2018, 55(2): 116
[46]	Muhsin S A, Al-Amidie M, Shen Z, et al. Biosens Bioelectron, 2022, 203: 113993
[47]	Zhang X, Xu X, Ren Y, et al. Sep Purif Technol, 2021, 255: 117343
[48]	Zeid A M, Abdussalam A, Hanif S, et al. Electrophoresis, 2022: 44(1): 15
[49]	Duca Z A, Speller N C, Cato M E, et al. Talanta, 2022, 241: 123227
[50]	Ben Frej M, D'Orlyé F, Duarte Junior G F, et al. Electrophoresis, 2022: 43(20): 2044
[51]	Scott A, Mills D, Birch C, et al. Lab Chip, 2019, 19(22): 3834
[52]	Quero R F, Bressan L P, Da Silva J A F, et al. Sensor Actuat B-Chem, 2019, 286: 301
[53]	Jender M, Novo P, Maehler D, et al. Anal Chem, 2020, 92(9): 6764
[54]	Pendharkar G, Lu Y, Chang C, et al. Sensor Actuat B-Chem, 2022, 354: 131109
[55]	Grist S M, Mourdoukoutas A P, Herr A E. Nat Commun, 2020, 11(1): 62371
[56]	Quan Z, Chen Y, Zhao X, et al. J Chromatogr A, 2022, 1665: 462797
[57]	Liénard-Mayor T, Furter J S, Taverna M, et al. Anal Chim Acta, 2020, 1135: 47
[58]	Guo W, Tao Y, Liu W, et al. Lab Chip, 2022, 22(8): 1556
[59]	Lin H, Hojaiji H, Lin S, et al. Lab Chip, 2019, 19(18): 2966
[60]	Wei K, Zhao J, Luo X, et al. Analyst, 2018, 143(6): 1468
[61]	Duarte-Junior G F, Lobo-Junior E O, Medeiros J I, et al. Electrophoresis, 2019, 40(5): 693
[62]	Zeid A M, Nasr J J M, Belal F, et al. Spectrochim Acta A, 2021, 246: 119021
[63]	Zhang Y, Zhang Y, Wang G, et al. J Chromatogr B, 2016, 1025: 33
[64]	Pan Q, Yamauchi K A, Herr A E. Anal Chem, 2018, 90(22): 13419
[65]	Rohani A, Moore J H, Kashatus J A, et al. Anal Chem, 2017, 89(11): 5757
[66]	Sahore V, Sonker M, Nielsen A V, et al. Anal Bioanal Chem, 2018, 410(3): 933
[67]	Cheng M, Shu H, Yang M, et al. Anal Chem, 2022, 94(11): 4666
[68]	Masár M, Hradski J, Vargová E, et al. Separations, 2020, 7(4): 72
[69]	Liu J, Zhao J, Li S, et al. Talanta, 2017, 165: 107
[70]	Zhang Y, Zhu L, He P, et al. Talanta, 2019, 197: 284
[71]	Khatri K, Klein J A, Haserick J R, et al. Anal Chem, 2017, 89(12): 6645
[72]	Park Y M, Lim S Y, Shin S J, et al. Anal Chim Acta, 2018, 1027: 57
[73]	Luo D, Ran F Y, Wu L, et al. Chinese Journal of Biotechnology, 2021, 37(2): 663
[73]	罗丹, 冉凤英, 武伦, 等. 生物工程学报, 2021, 37(2): 663
[74]	Woolley A T, Hadley D, Landre P, et al. Anal Chem, 1996, 68(23): 4081
[75]	Anazawa T, Uchiho Y, Yokoi T, et al. Lab Chip, 2017, 17(13): 2235
[76]	Yang X, Zhao J, Chen S, et al. J Chromatogr A, 2020, 16: 460693
[77]	Luo F, Lu Y, Li Z, et al. Sensor Actuat B-Chem, 2020, 325: 128784
[78]	Hennig S, Shu Z, Gutzweiler L, et al. Electrophoresis, 2022, 43(4): 621
[79]	Ouimet C M, D Amico C I, Kennedy R T. Anal Bioanal Chem, 2019, 411(23): 6155
[80]	Lietta E, Pieri A, Innocenti E, et al. Pharmaceutics, 2021, 13(12): 2135
[81]	Cabot J M, Breadmore M C, Paull B. Anal Chim Acta, 2018, 1000: 283
[82]	Ribeiro Da Silva M, Zaborowska I, Carillo S, et al. J Chromatogr A, 2021, 1651: 462336
[83]	Shi M, Huang Y, Zhao J, et al. Talanta, 2018, 179: 466
[84]	Huang X, Torres Castro K, Varhue W, et al. Electrophoresis, 2022, 43(12): 1275
[85]	Liang Y X, Pan J Z, Fang Q. Chinese Journal of Chromatography, 2021, 39(6): 567
[85]	梁怡萧, 潘建章, 方群. 色谱, 2021, 39(6): 567
[86]	Zhang Y, Zhu L, Zhang Y, et al. J Chromatogr A, 2018, 1555: 100
[87]	Zhang Y, Hu X, Wang Q. Microchem J, 2020, 157: 104876
[88]	Li M, Li D, Song Y, et al. J Colloid Interf Sci, 2022, 612: 23

Chip material	Advantages	Disadvantages	Processing technologies
Silicon	chemical corrosion resistance, good thermal stability, excellent strength and dissipation	fragile, poor insulation and light trans- mission, high cost	lithography, etching
Glass	easy surface modification, good electro permeability, light transmission and insulation, good biocompatibility	complex process conditions, high cost, long cycle, low bonding efficient	lithography, etching
Polymer	good chemical inertia, good optical properties, good thermal properties and electrical insulation, low cost	low surface hardness, poor heat resist- ance, hydrophobic surface	hot pressing, molding, 3D printing
Paper	low cost, good biocompatibility, self-drive ability, able to fix biomacromolecules	low surface strength, easy to evaporate, remaining and leaking in the chip channel	stereo lithography, inkjet printing, laser ablation

Chip material	Advantages	Disadvantages	Processing technologies
Silicon	chemical corrosion resistance, good thermal stability, excellent strength and dissipation	fragile, poor insulation and light trans- mission, high cost	lithography, etching
Glass	easy surface modification, good electro permeability, light transmission and insulation, good biocompatibility	complex process conditions, high cost, long cycle, low bonding efficient	lithography, etching
Polymer	good chemical inertia, good optical properties, good thermal properties and electrical insulation, low cost	low surface hardness, poor heat resist- ance, hydrophobic surface	hot pressing, molding, 3D printing
Paper	low cost, good biocompatibility, self-drive ability, able to fix biomacromolecules	low surface strength, easy to evaporate, remaining and leaking in the chip channel	stereo lithography, inkjet printing, laser ablation

Samples	Analytes	Material	Mode	Detection method	LOD	Ref.
Cell lysate	miRNA-141	glass	uniform	LIF	0.8×10^-15 mol/L	[60]
Model mixture	fructose	glass	uniform	CD	1.5×10^-4 mol/L	[61]
	galactose				1.8×10^-4 mol/L
	glucose				3.0×10^-4 mol/L
	lactose				2.2×10^-4 mol/L
	sucrose				7.4×10^-4 mol/L
Antiepileptic drug	vigabatrin, pregabalin,	glass	uniform	LIF	0.6×10^-12 mol/L	[62]
	gabapentin
Human urine	dopamine	glass	uniform	LIF	1.7×10^-9 mol/L	[63]
	norepinephrine				2.4×10^-9 mol/L
	serotonin				2.7×10^-9 mol/L
Single-cell lysate	animal proteome	glass	uniform	CD	/	[64]
Cell lines	mitochondria	PDMS	non-uniform	CD	/	[65]
Blood serum sample	preterm birth biomarkers	COC	uniform	LIF	1.2×10^-9 mol/L	[66]
Human urine	sialylated, N-glycan	COC	uniform	MS	/	[67]
Foodstuffs	carminic acid	PMMA	uniform	FL	6.9×10^-10 mol/L	[68]
Human urine	α-fetoprotein	PDMS	uniform	FL	7.2×10^-9 g/mL	[69]
Drinking water, milk	E. coli	PDMS	uniform	LIF	3.7×10² CFU/mL	[70]
Glycan, glycopeptide	glycoprotein	PMMA	uniform	MS	/	[71]
Food	E. coli	PC	non-uniform	AD	1.0×10² CFU/mL	[72]
	S. enteritidis				1.0 CFU/mL

Samples	Analytes	Material	Mode	Detection method	LOD	Ref.
Cell lysate	miRNA-141	glass	uniform	LIF	0.8×10^-15 mol/L	[60]
Model mixture	fructose	glass	uniform	CD	1.5×10^-4 mol/L	[61]
	galactose				1.8×10^-4 mol/L
	glucose				3.0×10^-4 mol/L
	lactose				2.2×10^-4 mol/L
	sucrose				7.4×10^-4 mol/L
Antiepileptic drug	vigabatrin, pregabalin,	glass	uniform	LIF	0.6×10^-12 mol/L	[62]
	gabapentin
Human urine	dopamine	glass	uniform	LIF	1.7×10^-9 mol/L	[63]
	norepinephrine				2.4×10^-9 mol/L
	serotonin				2.7×10^-9 mol/L
Single-cell lysate	animal proteome	glass	uniform	CD	/	[64]
Cell lines	mitochondria	PDMS	non-uniform	CD	/	[65]
Blood serum sample	preterm birth biomarkers	COC	uniform	LIF	1.2×10^-9 mol/L	[66]
Human urine	sialylated, N-glycan	COC	uniform	MS	/	[67]
Foodstuffs	carminic acid	PMMA	uniform	FL	6.9×10^-10 mol/L	[68]
Human urine	α-fetoprotein	PDMS	uniform	FL	7.2×10^-9 g/mL	[69]
Drinking water, milk	E. coli	PDMS	uniform	LIF	3.7×10² CFU/mL	[70]
Glycan, glycopeptide	glycoprotein	PMMA	uniform	MS	/	[71]
Food	E. coli	PC	non-uniform	AD	1.0×10² CFU/mL	[72]
	S. enteritidis				1.0 CFU/mL