Issue 30, 2024

Flow-electricity coupling fields enhance microfluidic platforms for efficient exosome isolation

Abstract

Recently, exosomes have emerged as important biomarkers for cancer diagnosis, playing a significant role in disease diagnosis. Consequently, efficient isolation of exosomes from complex body fluids is now a critical focus in clinical research. We have designed and fabricated an exosome separation chip, leveraging the synergies of flow and electric fields through 3D printing technology. This approach harnesses the combined strengths of both fields, substantially enhancing separation efficiency and purity. This also effectively reduced the voltage required to form an electric field (from 120 V down to 10 V), minimizing the risk of Joule heating, thereby preserving the structural integrity and biological activity of the exosomes. Compared with the standard exosome separation method of ultracentrifugation (UC), our chip offers numerous benefits: it is cost-effective (under 50 RMB), boasts a high recovery rate (64.8%) and high purity (almost 100%), achieves remarkable separation efficiency (within 30 minutes), and is straightforward to operate. Moreover, since an unmarked separation method is used, the separated exosomes can be directly used for downstream detection and analysis, which has certain practicality for future clinical research and application.

Graphical abstract: Flow-electricity coupling fields enhance microfluidic platforms for efficient exosome isolation

Supplementary files

Article information

Article type
Paper
Submitted
23 Apr 2024
Accepted
01 Jul 2024
First published
06 Jul 2024

Anal. Methods, 2024,16, 5335-5344

Flow-electricity coupling fields enhance microfluidic platforms for efficient exosome isolation

T. Hu, W. Han, Y. Zhou, W. Tu, X. Li and Z. Ni, Anal. Methods, 2024, 16, 5335 DOI: 10.1039/D4AY00740A

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