Typical strategy and research progress of efficient isolation methods of exosomes based on affinity interaction

doi:10.3724/SP.J.1123.2024.11004

Abstract

Abstract:

Exosomes form a subclass of extracellular vesicle that are secreted by most cells and found in nearly all body fluids, including blood, urine, saliva, amniotic fluid, and milk, as well as in various tissues and intercellular spaces. Exosomes have recently been recognized as crucial intercellular communication mediators, and an increasing number of studies have shown that exosomes are important liquid-biopsy tools that play irreplaceable roles in the diagnosis, prognosis, and treatment of diseases. The ability to isolate high-quality exosomes is a prerequisite for diagnosing and subsequently treating diseases in an accurate and repeatable manner. However, efficiently isolating exosomes from complex biological samples is challenging owing to their relatively low abundances and interference from non-vesicular macromolecules (such as cell debris and proteins). To date, various isolation techniques based on the physical, chemical, and biological characteristics of exosomes have been developed. Indeed, efficient affinity-interaction-based methods have recently overcome the limitations and drawbacks of traditional exosome isolation methods and are widely used in scientific research and clinical applications. This review focuses on exosome isolation and enrichment, and systematically reviews recent research progress on efficient isolation methods based on affinity interactions. Developmental prospects of exosome isolation and enrichment directions are analyzed with the aim of providing a reference for the construction and use of new exosome-isolation strategies.

Key words: exosomes, biomarkers, affinity interaction, isolation and enrichment, research progress

CLC Number:

O658

WANG Haiyan, XIE Peijuan, QIAO Xiaoqiang, ZHANG Liyuan. Typical strategy and research progress of efficient isolation methods of exosomes based on affinity interaction[J]. Chinese Journal of Chromatography, 2025, 43(5): 413-423.

Figures/Tables 7

Fig. 1 Biological functions of exosomes ESE: early-sorting endosome; MVBs: multivesicular bodies.

Fig. 2 Schematic of (a) Tim4@ILI-01 and (b) Fe3O4@SiO2-ILI-0l@Tim4 for exosome enrichment and downstream analysis[21,22]

Fig. 3 Exosome isolation by pH-responsive host-guest-based nanosystem (pH-HGN)[24]

Fig. 4 (a) Exosome isolation mechanism of TiO2-BSA-SPM[25]; (b) exosome adhesion on MB@CP via high-affinity choline phosphate-phosphatidylcholine (CP-PC) interactions[27]; (c) exosome enrichment in plasma using Fe3O4@SiO2@Eu2O3 nanomaterials[28]

Fig. 5 (a)Applications of SiO2@BSA@Fe-TA6 for exosome isolation and downstream analysis [29]; (b) an exosome detection platform based on the phospholipids-molecularly imprinted polymers-nanozyme-linked immunosorbent assay-surface-enhanced Raman scattering (PS-MIPs-NELISA-SERS)[31]; (c) an exosome isolation and detection platform based on g-C3N4 nanosheets (BCNNS)[32]

Table 1 Comparison of exosome-enrichment methods developed by our group, based on affinity-interaction

Approach	Capture efficiency/%	Advantages	Insufficiencies	Applications	Ref.
Tim4@ILI-01	85.2	high capture efficiency; easy nondestructive release; good biological activities of the captured exosomes	potentially exosome loss due to multiple mechanical centrifugation steps	sera of healthy persons and lung adenocarcinoma patients	[22]
Fe₃O₄@SiO₂- ILI-0l@Tim4	90.3	high-efficiency and high-throughput exosome capture and release; simple and quick sample handling	increased economic cost due to the employment of Tim4	high-throughput exosomal PD-L1 screening for accurately predicting anti-PD-1 response	[21]
pH-HGN	90.2	highly efficient homogeneous capture and rapid recovery of intact exosomes	biological interference of enriched exosome in clinical treatment due to the conjugation of anti-CD63 antibody	differentiating lung-cancer patients from healthy persons	[24]
SiO₂@BSA@ Fe-TA₆	85.4	label-free, universal, low-cost, and easy to scale-up exosome capture	difficulty in exosome elution	lung-cancer diagnosis and typing	[29]

Fig. 6 (a) Exosome-isolation process by a microfluidic chip and a perylene tetracarboxylic acid diimide derivative (PTCDI)-aptamer fluorescence signal transduction strategy for detecting exosomes[36]; (b) schematic depicting salivary exosome proteomic analysis and the high-throughput array detection of asthma biomarkers[37]; (c) scheme depicting exosome capture by a supporting lipid membrane (SLM)[38]; (d) exosome isolation and purification procedure using serpentine channels[39]

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