Single-cell sorting using integrated pneumatic valve droplet microfluidic chip

Abstract

Single-cell analysis and sorting have been increasingly prevalent in scientific study and industry in recent years. Droplet-based microfluidic systems are significant tools for single cell separation due to the advantages of high-throughput screening flux and relatively simple chip manufacturing. Herein, this work integrated single-cell droplet generation, incubation, and sorting functions into a single microfluidic chip using pneumatic microvalve for single-cell screening of hybridoma cells. The chip realized the generation, storage, incubation, and assay sorting of droplets in order by adjusting the switch of the microvalve. Numerical methods were used to simulate the effects of membrane size and pressure on valve deformation. Incubation results showed that fluorescent signals were generated in the droplets containing both hybridoma cells and microspheres under the control of pneumatic microvalves. In addition, the purity of target droplets was increased from 4.87% before sorting to 89.70% after sorting using fluorescence-activated droplet sorting platform, demonstrating the feasibility of the integrated chip with a pneumatic valve for single-cell screening. The integrated chip is proved to be operated efficiently with minimum cell loss and human labor through reducing the risk of droplet fusion and facilitating the development of automated devices. So, the present study provides an integrated design for microdroplet-based single-cell sorting with various applications, such as single-cell sequencing, antibody screening, and directed evolutionary studies.