A Dual-Channel Microfluidic Chip for Single Tobacco Protoplast Isolation and Dynamic Capture

Overview

Journal Micromachines (Basel)

Publisher MDPI

Date 2022 Dec 23

PMID 36557407

Authors

Huali Zhang

Qianqian Geng

Zhanghua Sun

Xiaoxiang Zhong

Ying Yang

Shuangyu Zhang

Ying Li

Yali Zhang

Lijun Sun

Affiliations

Soon will be listed here.

Abstract

Protoplasts are widely used in gene function verification, subcellular localization, and single-cell sequencing because of their complete physiological activities. The traditional methods based on tissues and organs cannot satisfy the requirement. Therefore, the isolation and capture of a single protoplast are most important to these studies. In this study, a dual-channel microfluidic chip based on PDMS with multi-capture cavities was designed. The design theory of the dual-channel microfluidic chip's geometry was discussed. The capture mechanism of the single cell in a dual-channel microfluidic chip was studied by simulation analysis. Our results showed that a single polystyrene microsphere or tobacco protoplast was successfully isolated and trapped in this chip. The capture efficiency of the chip was 83.33% for the single tobacco protoplast when the inlet flow rate was 0.75 μL/min. In addition, the dynamic capture of the polystyrene microsphere and tobacco protoplasts was also presented. Overall, our study not only provided a new strategy for the subsequent high throughput single protoplast research, but also laid a theoretical foundation for the capture mechanism of the single cell.

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