High-Resolution Dielectric Characterization of Single Cells and Microparticles Using Integrated Microfluidic Microwave Sensors

Microwave sensors can probe intrinsic material properties of analytes in a microfluidic channel at physiologically relevant ion concentrations. While microwave sensors have been used to detect single cells and microparticles in earlier studies, the synergistic use and comparative analysis of microwave sensors with optical microscopy for material classification and size tracking applications have been scarcely investigated so far. Here, we combined microwave and optical sensing to differentiate microscale objects based on their dielectric properties. We designed and fabricated two types of planar sensors: a coplanar waveguide (CPW) resonator and a split-ring resonator (SRR). Both sensors possessed sensing electrodes with a narrow gap to detect single cells passing through a microfluidic channel integrated on the same chip. We also show that standalone microwave sensors can track the relative changes in cellular size in real time. In sensing single 20-mu m-diameter polystyrene particles, signal-to-noise ratio values of approximately 100 for CPW and 70 for SRR sensors were obtained. These findings demonstrate that microwave sensing technology can serve as a complementary technique for single-cell biophysical experiments and microscale pollutant screening.

Automated summary

Microwave sensors combined with optical sensing can be used to probe material properties and track size changes of microscale objects. In this study, we designed and fabricated two types of planar sensors, the CPW resonator and the SRR, to detect single cells and particles. The results show that microwave sensing technology can serve as a complementary technique for single-cell biophysical experiments and microscale pollutant screening.