Direct and Label-Free Cell Status Monitoring of Spheroids and Microcarriers Using Microfluidic Impedance Cytometry

3D cellular spheroids/microcarriers (100 mu m-1 mm) are widely used in biomanufacturing, and non-invasive biosensors are useful to monitor cell quality in bioprocesses. In this work, a novel microfluidic approach for label-free and continuous-flow monitoring of single spheroid/microcarrier (hydrogel and Cytodex) based on electrical impedance spectroscopy using co-planar Field's metal electrodes is reported. Through numerical simulation and experimental validation, two unique impedance signatures (|Z(LF)| (60 kHz), |Z(HF)| (1 MHz)) which are optimal for spheroid growth and viability monitoring are identified. Using a closed-loop recirculation system, it is demonstrated that |Z(LF)| increases with breast cancer (MCF-7) spheroid biomass, while higher opacity (impedance ratio |Z(HF)|/|Z(LF)|) indicates cell death due to compromised cell membrane. Anti-cancer drug (paclitaxel)-treated spheroids also exhibit lower |Z(LF)| with increased cell dissociation. Interestingly, impedance characterization of adipose-derived mesenchymal stem cell differentiation on Cytodex microcarriers reveals that adipogenic cells (higher intracellular lipid content) exhibit higher impedance than osteogenic cells (more conductive due to calcium ions) for both microcarriers and single cell level. Taken together, the developed platform offers great versatility for multi-parametric analysis of spheroids/microcarriers at high throughput (approximate to 1 particle/s), and can be readily integrated into bioreactors for long-term and remote monitoring of biomass and cell quality.

Automated summary

A novel microfluidic approach for label-free and continuous-flow monitoring of single spheroid/microcarrier based on electrical impedance spectroscopy is reported, with unique impedance signatures identified for optimal spheroid growth and viability monitoring. The platform offers great versatility for multi-parametric analysis of spheroids/microcarriers at high throughput, and can be integrated into bioreactors for long-term and remote monitoring of biomass and cell quality.