High-throughput multi-gate microfluidic resistive pulse sensing for biological nanoparticle detection

A microfluidic resistive pulse sensing technique offers a simple method for detecting and analysing microparticles in various fields, yet it has challenges such as the noise during detection and low throughput as the signal obtained from a small single sensing aperture and particle position is nonuniform. This study presents a microfluidic chip with multiple detection gates in the main channel to enhance the throughput while maintaining a simple operational system. A hydrodynamic sheathless particle focusing on a detection gate by modulation of the channel structure and measurement circuit with a reference gate to minimize the noise during detection is used for detecting resistive pulses. The proposed microfluidic chip can analyse the physical properties of 200 nm polystyrene particles and exosomes from MDA-MB-231 with high sensitivity with an error of <10% and high-throughput screening of more than 200 000 exosomes per seconds. The proposed microfluidic chip can analyse the physical properties with high sensitivity, so that it can be potentially used for exosome detection in biological and in vitro clinical applications.

Automated summary

A microfluidic resistive pulse sensing technique is presented for detecting and analysing microparticles, with challenges in noise and low throughput. The study introduces a microfluidic chip with multiple detection gates to improve throughput while maintaining simplicity. The proposed chip uses hydrodynamic sheathless particle focusing to detect resistive pulses, with a reference gate to minimize noise. It achieves high sensitivity in analysing physical properties of particles and exosomes, offering potential for exosome detection in biological and clinical applications.