This work presents a miniaturized system combining, on the same microfluidic chip, capillarity and electrowetting-on-dielectric (EWOD) techniques for movement and control of fluids. The change in hydrophobicity occurring at the edge between a capillary channel and a hydrophobic layer is successfully exploited as a stop-and-go valve, whose operation is electronically controlled through the EWOD electrodes. Taking into account the variety of microfluidic operation resulting from the combination of the two handling techniques and their characteristic features, this work prompts the development of autonomous, compact and low-power consumption lab-on-chip systems.
Integration of capillary and EWOD technologies for autonomous and low-power consumption micro-analytical systems / Nardecchia, Marco; Bellini, Enrica; Llorca, Pablo R.; Caprini, Davide; Lovecchio, Nicola; Petrucci, Giulia; Caputo, Domenico; DE CESARE, Giampiero; Nascetti, Augusto. - In: PROCEDIA ENGINEERING. - ISSN 1877-7058. - STAMPA. - 168:(2016), pp. 1370-1373. (Intervento presentato al convegno 30th Eurosensors Conference, Eurosensors 2016 tenutosi a Budapest; Hungary nel 4-7 settembre 2016) [10.1016/j.proeng.2016.11.380].
Integration of capillary and EWOD technologies for autonomous and low-power consumption micro-analytical systems
NARDECCHIA, MARCO;CAPRINI, DAVIDE;LOVECCHIO, NICOLA;PETRUCCI, GIULIA;CAPUTO, Domenico;DE CESARE, Giampiero;NASCETTI, Augusto
2016
Abstract
This work presents a miniaturized system combining, on the same microfluidic chip, capillarity and electrowetting-on-dielectric (EWOD) techniques for movement and control of fluids. The change in hydrophobicity occurring at the edge between a capillary channel and a hydrophobic layer is successfully exploited as a stop-and-go valve, whose operation is electronically controlled through the EWOD electrodes. Taking into account the variety of microfluidic operation resulting from the combination of the two handling techniques and their characteristic features, this work prompts the development of autonomous, compact and low-power consumption lab-on-chip systems.File | Dimensione | Formato | |
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