Research progress on analysis of human papillomavirus by microchip capillary electrophoresis

doi:10.3724/SP.J.1123.2020.05016

Abstract

Abstract:

Human papillomavirus (HPV), is a common spherical DNA virus that can lead to six types of cancers later in life, which has recently garnered human's attention. Microchip capillary electrophoresis (MCE) has provided simple, fast, portable, and sensitive HPV typing assay assisted by a variety of signal amplification technologies. This review presents the latest research progress of MCE in routine HPV typing assays, including both of the MCE techniques and MCE combined with the nucleic acid amplification techniques for HPV assay. The introduction on the former part concerns the MCE system, the MCE chips design and electrophoretic separation methods. The typical MCE system includes high voltage power supply, microfluidic chip of separation, sample injection, electrolyte cell, detection unit and so on. Four different chips are reviewed, containing straight separation channel, T-channel, serpentine channel and dual channel, because these microchips are the most used in the last decade. Furthermore, the high integration and high throughput on a single chip are often integrated the sample preparation unit on a chip. The advantages and disadvantages of different designed microchips are introduced at the same time. The separation methods of chip electrophoresis are briefly introduced. With the development and application of MCE for HPV detection, the separation time is greatly shortened from a few hours to several minutes. The review on the second part gives the comments on various kinds of nucleic acid amplification technologies coupled with MCE for HPV assay. Firstly, the comparative analysis is given on the polymerase chain reaction (PCR) combined with MCE, loop-mediated isothermal amplification (LAMP), PCR combined with restriction fragment length polymorphism (RFLP) for HPV DNA detection, and nucleic acid sequence based amplification (NASBA) for the detection of HPV mRNA, nested PCR and so on. Secondly, the reviews on the other methods beside MCE are also summarized, including the PCR coupled with Fourier transform-infrared spectroscopy (FT-IR spectroscopy), nanotechnology, DNA probes combined with electrochemical methods, reductive Cu(Ⅰ) particles catalyzed Zn-doped MoS₂ quantum dots and T7 exonuclease with electrochemiluminescence, LAMP with CRISPR/Cas12a based lateral. In these non-MCE methods, the electrochemical sensing, e. g., impedimetric detection, pulse voltammetry method and flow biosensor, is an ideal method due to its low background signal and excellent time control ability. Finally, although MCE technologies have been developed and the developed instruments are applied in recent years, there are still some challenges in MCE techniques, methods and applications. The first challenge faced in the application of MCE technique in HPV typing assay is that the MCE device can not be well utilized for the detection of HPV with high resolution and high sensitivity, because MCE can not do signal amplification of HPV nucleic acid. The second challenge is that even though some researchers have successfully integrated PCR and MCE on one chip, the technique still faces difficulty for wide application and there is still no really integrated PCR-MCE chip for HPV detection. The third one is the MCE technique is lack for the manufacture of miniaturized and automatic instrument. At the end of review, the authors' insights are given on the development of automatic, fast, high stable and reliable detection in the HPV typing via the portable MCE device.

Key words: microchip capillary electrophoresis (MCE), human papillomavirus (HPV), human papillomavirus typing, review

LIN Xuexia, WANG Chenjing, LIN Jin-Ming. Research progress on analysis of human papillomavirus by microchip capillary electrophoresis[J]. Chinese Journal of Chromatography, 2020, 38(10): 1179-1188.

Figures/Tables 7

Fig. 1 Human papillomavirus (HPV) DNA/mRNA detection based on the microchip capillary electrophoresis (MCE) a. composition of the MCE system; b. schematic diagram of the MCE chip commonly used; c. test result report by MCE. S, SW, B and BW indicated sample solution, sample waste, buffer and buffer waste, respectively.

Fig. 2 Schematic diagrams of four common chip channels a. straight channel; b. T channel; c. serpentine channel; d. dual channel; e. double channels.

Fig. 3 Detection of HPV types by PCR-MCE a. DNA extraction and PCR assay; b. HPV analysis based on MCE; c. simultaneous detection of HPV16 and HPV18. PCR: polymerase chain reaction.

Fig. 4 Schematic diagram of PCR-RFLP-MCE for automatic detection of HPV[26] a. PGMY09/11 primes for the amplification of the potential multiple HPV DNAs; b. DNA analysis on MCE; c. the sites of different restriction endonucleases and the sizes of RFLP; d. automatic typing software for RFLP fragments. RFLP: restriction fragment length polymorphism.

Fig. 5 Amplification of HPV E6/E7 mRNA based on nucleic acid sequence based amplification (NASBA)

Fig. 6 Detection of E6/E7 mRNA of HPV16 and HPV18 by NASBA-MCE

Table 1 Signal amplification techniques coupled with detection method except MCE for the determination of HPV

HPV technologies	Targets	Detection method	Ref.
PCR	HPV DNA	FT-IR spectroscopy	[34]
DNA nanobiosensor (reduced graphene oxide, multiwalled carbon nanotubes, gold nanoparticle), DNA probe	HPV18 DNA	electrochemical (pulse voltammetry)	[35]
Polyaniline Matrix containing gold nanoparticles, DNA probe	HPV6, HPV11, HPV16, HPV31, HPV33, HPV45, and HPV58	electrochemical (impedimetric detection)	[36]
Reductive Cu(Ⅰ) particles catalyzed Zn-doped MoS2 quantum dots, T7 exonuclease	HPV16 DNA	electrochemiluminescence	[37]
Magnetic microparticles	HPV16 and HPV18 DNA	DNA zyme oligonucleotides based colorimetric detection	[38]
Loop-mediated isothermal amplification (LAMP)	HPV16 and HPV18 DNA	CRISPR/Cas12a based Lateral flow biosensor	[39]
LAMP	HPV16 and HPV18 DNA	colorimetric detection	[24]
In situ hybridization	HPV E6/E7 mRNA	in situ hybridization	[40]
In situ hybridization	HPV E6/E7 mRNA	in situ hybridization	[41]

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