Research progress in the application of external field separation technology and microfluidic technology in the separation of micro/nanoscales

doi:10.3724/SP.J.1123.2020.12032

Abstract

Abstract:

The micro/nanoscales concerns interactions of entities with sizes in the range of 0.1-100 μm, such as biological cells, proteins, and particles. The separation of micro/nanoscales has been of immense significance for drug development, early-stage cancer detection, and customized precision therapy. For example, in recent years, rapid advances in the field of cell therapy have necessitated the development of simple and effective cell separation techniques. The isolation technique allows the collection of the required stem cells from complex samples. With the development of materials science and precision medicine, the separation of particles is also critical. The key physicochemical properties of micro/nanoscales are highly dependent on their specific size, shape, functional group, and mobility (based on the charged characteristics), which control their performance in the separation system. The current demand has made the simultaneous innovation of a separation system and an on-line detection platform imperative. Accordingly, various analytical methods involving the use of external forces, such as the flow field, magnetic field, electric field, and acoustic field, have been used for micro/nanoscales separation. Based on the physical and chemical parameters of the separation materials, these analytical methods can select different external force fields for micro/nanoscales separation, enabling real-time, accurate, efficient, and selective separation. However, at present, most of the applied field separation technologies require complex equipment and a large sample amount. This makes it crucial to miniaturize and integrate separation technologies for low-cost, rapid, and accurate micro/nanoscales separation. Microfluidic technology is a representative micro/nanoscales separation technology. It requires only a small volume of liquid, making it cost-effective; its high throughput enables continuous separation and analysis; its fast response in a microchip can allow many reactions; and finally, the miniaturization of the device allows the coupling of multiple detectors with the microchip. With the continuous growth and progress of microfluidic technology, some microfluidic platforms are now able to achieve the non-destructive separation of cells. They also enable on-line detection, offer high separation efficiency, and allow rapid separation for different biological samples. This review primarily summarizes recent advances in microfluidic chips based on flow field, electric field, magnetic field, acoustic field, and field separation technologies to improve the micro/nanoscales separation efficiency. This review also discusses the various external force fields of micro/nanoscales, such as a microparticle, single cell separation of substances classified introduction, and summarizes the advantages and disadvantages of their application and development. Finally, the prospect of the combined application of external field separation technology and microfluidic technology in the early screening of cancer cells and for precise micro/nanoscales separation is discussed, and the advantages and potential applications of the combined technology are proposed.

Key words: microfluidic, micro/nanoscales, active field separation, review

CLC Number:

O658

CUI Jiaxuan, LIU Lu, LI Donghao, PIAO Xiangfan. Research progress in the application of external field separation technology and microfluidic technology in the separation of micro/nanoscales[J]. Chinese Journal of Chromatography, 2021, 39(11): 1157-1170.

Figures/Tables 7

Fig. 1 Four widely used electric field separation techniques a. capillary electrophoresis (CE); b. dielectrophoresis (DEP); c. electrical field flow fractionation (EIFFF); d. induced charged electroosmosis (ICEO). EP: electrophoresis; EOF: electroosmotic flow.

Fig. 2 Separation systems based on microchip electrophoresis a. schematic diagram of the separation device and separation process and movement of 4.8-μm particles in the separation channel as a function of the applied voltage[59]; b. diagram of cross-type microfluidic glass chip[60].

Fig. 3 Microfluidic separation systems based on dielectrophoresis technology a. schematic illustration of the microchannel for the measurement of the lateral migration of the yeast cells red color indicates the electric field strength[67]; b. diagram of ionic liquid electrode dielectrophoresis device[68]; c. schematic showing the interface of the DEP microelectrode array chip with the scanning electron microscope and microscopic images of human tissue leukemia cells intercepted at positive dielectrophoresis (pDEP) in a micromotor array chip[69]; d. schematic diagram of direct curren-dielectrophoresis (DC-DEP) microfluidic chip device with asymmetric orifice[70]; e. DEP microfluidic chip device schematic diagram[71].

Fig. 4 Schematic diagram of open-tubular radially cyclical electric field-flow fractionation (OTR-CyEIFFF)[45]

Fig. 5 Microfluidic separation systems based on induced charge electroosmosis a. schematic diagrams and image of ICEO particle separation device[79]; b. Schematic diagram of trajectories and separation of 5 μm polystyrene particle (PS) and silicon microbeads[79].

Fig. 6 Microfluidic separation systems based on magnetic field a. concept of free-flow magnetophoresis[89]; b. schematic of 3D magnetic trap integrated in polymerization microfluidic device[90]; c. schematic view of the microfluidic chip and 3D schematic view of the particles moving across the microchannel (100 mm wide) in between the magnetic poles[91]; d. Schematic diagram of magneto-optic sensor particles (MOSePs) in microfluidic device[92].

Fig. 7 Microfluidic separation systems based on acoustic field a. application of microfluidic chip to red blood cell in experiments[99]; b. schematic illustration and image of the high-throughput tilted-angle standing surface acoustic waves (taSSAW) device for cancer cell separation[100]; c. schematic diagram showing the travelling surface acoustic wave (taTSAW) based sheathless particle focusing and integrated particle separation[101]; d. schematic of the acoustofluidic multi-well plate[102]; e. schematic of the SSAW focusing device[103].

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