Vortexing-generated high throughput single-cell droplets for facile analysis of multiplexed microRNA dynamic secretion

• Published in: Biosensors & bioelectronics Vol. 257; p. 116303
• Main Authors: Zhu, Fengjiao, Long, Yangyang, Shi, Weiwei, Li, Bin, Ji, Yahui, Bai, Xue, Liu, Xianming, Qi, Dongyuan, Sun, Bo, Zhang, Fuyin, Liu, Tingjiao, Lin, Bingcheng, Lu, Yao
• Format: Journal Article
• Language: English
• Published: England Elsevier B.V 01.08.2024
• Subjects: Dynamics; Secreted microRNA; Single-cell secretion analysis; Vortexing; Vortexing; Secreted microRNA; Dynamics; Single-cell secretion analysis
• ISSN: 0956-5663; 1873-4235
• DOI: 10.1016/j.bios.2024.116303

Discriminating secretory phenotypes provides a direct, intact, and dynamic way to evaluate the heterogeneity in cell states and activation, which is significant for dissecting non-genetic heterogeneity for human health studies and disease diagnostics. In particular, secreted microRNAs, soluble signaling molecules released by various cells, are increasingly recognized as a critical mediator for cell-cell communication and the circulating biomarkers for disease diagnosis. However, single-cell analysis of secreted miRNAs is still lacking due to the limited available tools. Herein, we realized three-plexed miRNA secretion analysis over four time points from single cells encapsulated in picoliter droplets with extreme simplicity, coupling vortexing-generated single-cell droplets with multiplexed molecular beacons. Notably, our platform only requires pipetting and vortexing steps to finish the assay setup within 5 min with minimal training, and customized software was developed for automatic data quantification. Applying the platform to human cancer cell lines and primary cells revealed previously undifferentiated heterogeneity and paracrine signaling underlying miRNA secretion. This platform can be used to dissect secretion heterogeneity and cell-cell interactions and has the potential to become a widely used tool in biomedical research. •Developed a facile process to generate high throughput droplets using a vortexing mixer.•Revealed previously undifferentiated heterogeneity underlying miRNA secretion.•Revealed the critical roles of secreted miRNA involved in cell-cell communication.