基于电驱动在线快速分离富集技术的研究进展

doi:10.3724/SP.J.1123.2020.07026

摘要/Abstract

摘要：

样品前处理能将待测物从复杂基质中预先分离富集出来，以提高分析方法的灵敏度、选择性和准确性，是复杂样品分析的关键步骤。样品前处理是一个非自发的、从无序到有序的熵减过程，不仅费时费力，还极易引起误差。向体系输入能量和降低体系熵值可以增强分离富集效果，加快样品制备过程。将电场引入在线样品前处理，既能向体系做功，又能驱动样品定向迁移，使前处理的熵减过程快速顺利进行，是快速样品制备的有效途径。基于电驱动的在线分离富集技术综合了多种加速策略：（1）以电场形式向体系输入能量，加速传质和传热过程；（2）采用电渗流、电泳等电驱动定向流实现样品在分离、富集、检测各步骤之间的定向迁移，保证样品前处理与检测顺利进行；（3）利用在线联用技术集成样品前处理与分析检测各步骤，从而提高自动化程度，减少人为误差；（4）通过微型化装置或微萃取方法提高样品制备效率，缩短样品制备时间。该文总结了近10年与基于电驱动的在线快速分离富集技术相关的90多篇文献，综述了该技术领域的研究进展，探讨了电驱动毛细管在线快速分离富集技术、电驱动芯片在线快速分离富集技术和电驱动膜萃取在线分离富集技术各自的优势和潜力，并展望了该类技术的发展与应用趋势。

关键词: 电驱动, 在线分离富集, 样品前处理, 快速检测

Abstract:

Sample preparation is a critical step in complex sample analysis, which enables analyte isolation and preconcentration from a complex matrix. Therefore, sample preparation is an effective approach to enhance the sensitivity, selectivity, and accuracy of the analytical method. However, the transfer of target analytes from a random state in the original sample matrix to a highly ordered pre-analysis state involves an entropy reduction process that cannot occur spontaneously. Therefore, sample preparation is always a time-consuming, labor-intensive, and error-prone process. Introducing additional energy or reducing the entropy of the system can enhance the separation and enrichment effects as well as accelerate sample preparation. The introduction of an electric field into an online sample preparation system can not only introduce additional energy into the system, but also drive the directional migration of the sample among the separation, enrichment, and detection processes, ensuring that the entropy reduction progresses smoothly. These advantages of electrically-driven force based online separation and enrichment techniques make them effective for accelerating sample preparation. Typically, there are four acceleration strategies in electrically-driven force based online separation and enrichment techniques: (1) the additional energy of the electric field is added into the system to accelerate mass transfer and energy exchange; (2) electrically-driven flows, including electroosmotic flow and electrophoretic flow, are applied to drive the directional migration of the sample among the separation, enrichment, and detection processes, ensuring that sample preparation and analysis are executed smoothly; (3) the online integration technique is applied to enhance the automaticity of the entire sample preparation and analysis processes, and reduce errors from manual operation; (4) device miniaturization or size reduction methods such as microextraction are applied to enhance the sample preparation efficiency and reduce the time consumed. This review summarizes the progress in electrically-driven force based online rapid separation and enrichment techniques in the last ten years. In this specific research area, more than one hundred research papers are published each year, and can be classified into three types based on the electrically-driven force based online rapid separation and enrichment techniques considered: capillary, microchip, and membrane extraction. Among these, over 50% of the studies focused on electrically-driven capillary force based online rapid separation and enrichment techniques. By applying a high-voltage electric field at the two ends of a capillary, charged species in the capillary can migrate along the direction of the medium. This makes the electrically-driven capillary technique not only fast, highly efficient, and low-cost, but also effective for rapid sample preparation. Typically, two modes of electrically-driven capillary force based online rapid separation and enrichment techniques are employed: online capillary electrophoretic separation and enrichment, and online microextraction-capillary electrophoresis. Device miniaturization from the capillary to microchip through microelectronic mechanical systems and microfluidics enables small-amount sample preparation and analysis, and is also advantageous due to being rapid and efficient, as well as low energy- and sample-consuming. The specific easy-integration trait of microchip devices enables the online integration of multi-step sample preparation and analysis. On the other hand, the controllable electrically-driven force can be used for both, directional flow transfer between different functional units in the microchip as well as for dynamic control of the electrically fluid pump and valve. Online microchip electrophoretic separation and enrichment, and online microextraction-microchip electrophoresis, are two common modes of microchip electrically-driven force based online rapid separation and enrichment techniques. In electrically-driven membrane extraction online separation and enrichment techniques, a supporting liquid membrane is used to eliminate the matrix interference, enabling large-scale real sample application. These techniques have received increasing attention in the research area of electrically-driven force based online separation and enrichment. Overall, rapid separation and enrichment techniques are highly desired in complex sample analysis, and electrically-driven force based online approaches offer significant application potential, especially in food, the environment, and medicine.

Key words: electrically-driven force, online separation and enrichment, sample preparation, rapid detection

刘玉兰, 陈雅莉, 肖小华, 夏凌, 李攻科. 基于电驱动在线快速分离富集技术的研究进展[J]. 色谱, 2020, 38(10): 1197-1205.

LIU Yulan, CHEN Yali, XIAO Xiaohua, XIA Ling, LI Gongke. Research progress of electrically-driven force based online rapid separation and enrichment techniques[J]. Chinese Journal of Chromatography, 2020, 38(10): 1197-1205.

图/表 4

图1 近10年关于电驱动在线快速分离富集技术的文献报道情况

Fig. 1 Literature reports on electrically-driven force based online rapid separation and enrichment techniques in recent 10 years Literature source: Web of Science; keywords (2010-2020): capillary electrophoresis (CE), microchip electrophoresis (MCE), online concentration, solid-phase (micro)extraction, liquid-phase (micro)extraction, electromembrane extraction (EME).

图2 简单电场聚焦-CE在线分离富集技术示意图

Fig. 2 Schematic diagram of simple electric fields stacking-CE online separation and enrichment technique

图3 微固相萃取-毛细管电泳在线联用方式

Fig. 3 Online integrated micro solid-phase extraction-capillary electrophoresis methods

图4 芯片式电膜萃取-高效液相色谱-质谱在线联用示意图[86]

Fig. 4 Schematic diagram of online combination of on-chip EME-HPLC-ESI-MS[86]

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