Floating-Electrode-Enabled Impedance Cytometry for Single-Cell 3D Localization

As a label-free, low-cost, and noninvasive tool, impedance measurement has been widely used in single-cell characterization analysis. However, due to the tiny volume of cells, the uncertainty of the spatial position in the microchannel will bring measurement errors in single-cell electrical parameters. To overcome the issue, we designed a novel microdevice configured with a coplanar differential electrode structure to accurately resolve the spatial position of single cells without constraining techniques such as additional sheath fluids or narrow microchannels. The device precisely localizes single cells by measuring the induced current generated by the combined action of the floating electrode and the differential electrodes when single cells flow through the electrode-sensing area. The device was experimentally validated by measuring 6 mu m yeast cells and 10 mu m particles, achieving spatial localization with a resolution down to 2.1 mu m (about 5.3% of the channel width) in lateral direction and 1.2 mu m (about 5.9% of the channel height) in the vertical direction at a flow rate of 1.2 mu L/min. In addition, by comparing measurement of yeast cells and particles, it was demonstrated that the device not only localizes the single cells or particles but also simultaneously characterizes their status properties such as velocity and size. The device offers a competitive electrode configuration in impedance cytometry with the advantages of simple structure, low cost, and high throughput, promising cell localization and thus electrical characterization.

Automated summary

In this study, a novel microdevice was designed to accurately determine the spatial position of single cells by measuring the induced current generated by the combined action of the floating electrode and the differential electrodes. The device was experimentally validated to achieve precise localization of yeast cells and particles, and simultaneously characterize their velocity and size.