Recent advances in isolation and detection of circulating tumor cells with a microfluidic system

doi:10.3724/SP.J.1123.2021.07009

Abstract

Abstract:

The isolation and analysis of circulating tumor cells (CTCs) is an important issue in tumor research. CTCs in peripheral blood, which are important biomarkers of liquid biopsy, are closely related to the occurrence of cancer and are used to monitor the effect of treatment on cancer patients. However, the number of CTCs in the blood samples of cancer patients is very low, usually being present at only 0-10 CTCs/mL. Therefore, prior to the detection of CTCs, it is important to preprocess clinical blood samples for efficient separation and enrichment. With the advantages of low sample consumption, high separation efficiency, ease of automation and integration, microfluidic chips can be a suitable platform for the isolation of CTCs. In the last few years, CTC separation and detection using microfluidic chips have developed rapidly, and a variety of detection methods have been developed. According to the technical principle used, microfluidics for CTC separation can be divided into biological property-based methods and physical property-based methods. The biological property-based methods mainly depend on the interaction between the antigen and antibody, or the specific binding of the aptamer and target. These methods have high selectivity but low efficiency and recovery rates. Physical separation is based on the physical properties of CTCs such as their size, density, and dielectric properties. For example, CTCs can be blocked or captured by the microstructure in the channels of microfluidic chips, sorted by external physical fields (acoustic, electrical, magnetic), or screened by micro-scale hydrodynamics. Physical property-based methods generally have a higher flux but lower separation purity. However, the advantages of biological property-based methods and physical property-based methods can be integrated to provide microfluidic chips having better separation performance. In addition to the direct positive enrichment of CTCs, a negative enrichment strategy can also be adopted. The influence of direct screening on the activity of CTCs can be avoided by selectively removing white blood cells. In this paper, recent advances in microfluidics utilized in the isolation of CTCs, including physical and immune methods and positive and negative enrichment, are reviewed. We summarized the technical principles, detection methods, and research progress in CTC separation and detection using microfluidic chips. Developing trends in microfluidics for CTC separation and analysis are also discussed.

Key words: microfluidics, circulating tumor cells (CTCs), separation and detection

CLC Number:

O658

CAO Rongkai, ZHANG Min, YU Hao, QIN Jianhua. Recent advances in isolation and detection of circulating tumor cells with a microfluidic system[J]. Chinese Journal of Chromatography, 2022, 40(3): 213-223.

Figures/Tables 6

Fig. 1 Microfluidics for separation of circulating tumor cells (CTCs) with biological property-based methods a. microfluidics with epithelial cell adhesion molecule (EpCAM) antibody-modified nanofibers[38]; b. microfluidics with cancer cell-replicated surface[40]; c. microfluidics with fluidic multivalent membrane nanointerface[41]. PLGA: poly lactic-co-glycolic acid; PEG: polyethylene glycol; CellRePDMS: cell-replicated topological structure on the surface of polydimethylsiloxane; PBMC: peripheral blood mononuclear cell.

Fig. 2 Microfluidics for separation of circulating tumor cells with physical property-based methods a. acoustic CTC separation chip[47]; b. sequential size-based chip[50]; c. inertial force-based straight chip[52]. WBC: white blood cell; SAW: surface acoustic wave; PDMS: polydimethylsiloxane.

Fig. 3 Microfluidics for separation of circulating tumor cells using integrated methods a. microfluidics integrating lateral filter arrays with immunoaffinity[62]; b. antibody-functional microsphere-integrated filter chip with inertial microflow[63]; c. deterministic lateral displacement (DLD)-patterned chip modified with multivalent aptamer-functionalized nanospheres[65]. AP: aptamer; GSH: glutathione.

Fig. 4 Microfluidics for negative enrichment of circulating tumor cells a. 3D-printed microfluidic device with immunocapture channels and microfiltration[66]; b. microfluidic chip integrated with DLD arrays and magnetic field[68]; c. CD45 antibody-based MACS combined with an inertial focusing chip[69]. MACS: magnetic activated cell sorting; RBC: red blood cell; PLT: platelet.

Table 1 Separation methods of circulating tumor cells with microfluidics

Methods	Sample	Throughput/ (mL/h)	Recovery/ %	Depletion of WBCs/%	Viability/ %	Ref.
Biological property-based methods
Antigen modified microstructure	PC3 cells spiked into whole blood	1.2	~92	14 (purity)	~95	[36]
Aptamer functionalized nanointerface	Cancer cells suspended in buffer	0.35	~91	>99.9	~98	[41]
Antigen coated 3D scaffold	MCF-7 cells and WBCs suspended	6	~93	N/A	~91	[42]
	in PBS
Physical property-based methods
Dielectrophoretic field-flow	MDA-MB-435 and PBMN cells	90	~92	>95	~90	[46]
fractionation	suspended in buffer
Surface acoustic wave	Cancer cells and WBCs suspended	7.5	>86	>97	N/A	[47]
	in PBS
Biomimetic filtration membranes	MDA-MB-231 cells spiked into diluted	30	~90	>45 (purity)	~91	[49]
	blood
Deterministic lateral displacement	A549 and K562 cells spiked into	60	>96	>99.99	>98	[51]
	diluted blood
Inertial focusing	A549 cells spiked into lysed blood	180	~94	~79 (purity)	N/A	[56]
Integrated methods
Lateral filter arrays with immunoaffinity	L3.6pl cells spiked into diluted blood	3.6	~95	>99.5	~84	[62]
Immunobeads integrated filter chip	MCF-7 cells spiked into lysed whole	3	>85	~40 (purity)	N/A	[63]
with inertial flow	blood
Multivalent aptamer modified DLD-array	Cancer cells spiked into whole blood	1	~84	~99.99	~96	[65]
Negative enrichment strategy
Immunocapture channels with	Cancer cells spiked into whole blood	0.5	>90	~96	>90	[66]
microfiltration
DLD arrays integrated with MACS	Cancer cells spiked into whole blood	8	~97	>99.9	N/A	[67]
and inertial focusing
MACS combined with inertial focusing	Cancer cells spiked into whole blood	168	~86	~99.97	N/A	[69]

Fig. 5 On-chip analysis of circulating tumor cells a. optically combined encoding of single CTC on chip[76]; b. visual quantifiable detection of CTCs in a volumetric bar-chart chip[83]; c. electrochemical determination of iron ions leaking from CTCs by DPV technique[84]. BTC: bis(trichloromethyl)carbonate; magMOF: magnetic metal-organic framework; FITC-GOD: fluorescein isothiocyanate-glucose oxidase; CB: conduction band; VB: valence band.

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