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基于微流控的细胞外囊泡分离技术的进展与障碍。

Advancement and obstacles in microfluidics-based isolation of extracellular vesicles.

机构信息

Biomedical Engineering Department, Lund University, Ole Römers väg 3, 221 00, Lund, Sweden.

出版信息

Anal Bioanal Chem. 2023 Mar;415(7):1265-1285. doi: 10.1007/s00216-022-04362-3. Epub 2022 Oct 26.

DOI:10.1007/s00216-022-04362-3
PMID:36284018
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9928917/
Abstract

There is a great need for techniques which enable reproducible separation of extracellular vesicles (EVs) from biofluids with high recovery, purity and throughput. The development of new techniques for isolation of EVs from minute sample volumes is instrumental in enabling EV-based biomarker profiling in large biobank cohorts and paves the way to improved diagnostic profiles in precision medicine. Recent advances in microfluidics-based devices offer a toolbox for separating EVs from small sample volumes. Microfluidic devices that have been used in EV isolation utilise different fundamental principles and rely largely on benefits of scaling laws as the biofluid processing is miniaturised to chip level. Here, we review the progress in the practicality and performance of both passive devices (such as mechanical filtering and hydrodynamic focusing) and active devices (using magnetic, electric or acoustic fields). As it stands, many microfluidic devices isolate intact EV populations at higher purities than centrifugation, precipitation or size-exclusion chromatography. However, this comes at a cost. We address challenges (in particular low throughput, clogging risks and ability to process biofluids) and highlight the need for more improvements in microfluidic devices. Finally, we conclude that there is a need to refine and standardise these lab-on-a-chip techniques to meet the growing interest in the diagnostic and therapeutic value of purified EVs.

摘要

从生物体液中以高回收率、高纯度和高通量方式对细胞外囊泡(EVs)进行可重现分离,这一需求非常迫切。开发从微量样本体积中分离 EVs 的新技术,对于在大型生物库队列中进行基于 EV 的生物标志物分析以及改善精准医疗中的诊断分析至关重要。基于微流控的新型设备的发展为从小样本量中分离 EVs 提供了工具。用于 EV 分离的微流控设备采用了不同的基本原理,并且主要依赖于缩放定律的优势,因为生物流体处理被小型化到芯片级别。在这里,我们综述了被动设备(例如机械过滤和流体动力聚焦)和主动设备(使用磁场、电场或声场)的实用性和性能方面的进展。目前,许多微流控设备可以以比离心、沉淀或排阻色谱更高的纯度分离完整的 EV 群体。然而,这是有代价的。我们解决了一些挑战(特别是低通量、堵塞风险以及处理生物流体的能力),并强调需要对微流控设备进行更多改进。最后,我们得出结论,需要对这些芯片实验室技术进行改进和标准化,以满足对纯化 EV 的诊断和治疗价值日益增长的兴趣。

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3
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Adv Nutr. 2025 Jun;16(6):100430. doi: 10.1016/j.advnut.2025.100430. Epub 2025 Apr 25.
4
Consistency in bacterial extracellular vesicle production: key to their application in human health.细菌细胞外囊泡生产的一致性:其在人类健康中应用的关键。
Extracell Vesicles Circ Nucl Acids. 2025 Jan 17;6(1):1-20. doi: 10.20517/evcna.2024.76. eCollection 2025.
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