Selective Retrieval of Individual Cells from Microfluidic Arrays Combining Dielectrophoretic Force and Directed Hydrodynamic Flow

• Published in: Micromachines (Basel) Vol. 11; no. 3; p. 322
• Main Authors: Thiriet, Pierre-Emmanuel, Pezoldt, Joern, Gambardella, Gabriele, Keim, Kevin, Deplancke, Bart, Guiducci, Carlotta
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 20.03.2020; MDPI
• Subjects: Dielectrophoresis; dielectrophoresis (dep); drop-seq; Electrodes; electrokinetics; Etching; Glass substrates; hydrodynamic trapping; Investigations; Ion beams; Localization; Methods; Microfluidic devices; mrna sequencing; Polydimethylsiloxane; Population; Recovery; Retrieval; Silicon wafers; Silicone resins; single-cell array; single-cell microfluidics; single-cell recovery; Trapping; tridimensional electrodes; Germany; Drop-seq; mRNA sequencing; single-cell microfluidics; single-cell array; dielectrophoresis (DEP); single-cell recovery; electrokinetics; hydrodynamic trapping; tridimensional electrodes
• ISSN: 2072-666X; 2072-666X
• DOI: 10.3390/mi11030322

Hydrodynamic-based microfluidic platforms enable single-cell arraying and analysis over time. Despite the advantages of established microfluidic systems, long-term analysis and proliferation of cells selected in such devices require off-chip recovery of cells as well as an investigation of on-chip analysis on cell phenotype, requirements still largely unmet. Here, we introduce a device for single-cell isolation, selective retrieval and off-chip recovery. To this end, singularly addressable three-dimensional electrodes are embedded within a microfluidic channel, allowing the selective release of single cells from their trapping site through application of a negative dielectrophoretic (DEP) force. Selective capture and release are carried out in standard culture medium and cells can be subsequently mitigated towards a recovery well using micro-engineered hybrid SU-8/PDMS pneumatic valves. Importantly, transcriptional analysis of recovered cells revealed only marginal alteration of their molecular profile upon DEP application, underscored by minor transcriptional changes induced upon injection into the microfluidic device. Therefore, the established microfluidic system combining targeted DEP manipulation with downstream hydrodynamic coordination of single cells provides a powerful means to handle and manipulate individual cells within one device.