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Related Experiment Video

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Separating Beads and Cells in Multi-channel Microfluidic Devices Using Dielectrophoresis and Laminar Flow
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Reconfigurable Prototyping Microfluidic Platform for DEP Manipulation and Capacitive Sensing.

Amine Miled, Benoit Auclair, Anis Srasra

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    Summary

    This study introduces a novel rapid prototyping platform for dielectrophoretic microfluidic manipulation and capacitive cell sensing, enhancing microfluidic device development and cell analysis capabilities.

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    Area of Science:

    • Microfluidics
    • Biotechnology
    • Electrical Engineering

    Background:

    • Microfluidic devices are crucial for cell manipulation and sensing.
    • Existing platforms often lack reconfigurability and advanced sensing capabilities.

    Purpose of the Study:

    • To present a new rapid prototyping platform for dielectrophoretic microfluidic manipulation and capacitive cell sensing.
    • To detail the platform's reconfigurable design, signal control, and capacitive sensing features.

    Main Methods:

    • Developed a reconfigurable platform with 4 programmable output channels and 64 electrodes.
    • Integrated an advanced capacitive sensor with a sampling frequency up to 5 kHz.
    • Utilized a new assembly technique for reusable microfluidic chips using anisotropic adhesive conductive film, epoxy, and PDMS.

    Main Results:

    • Demonstrated signal amplitude accuracy (+/-10%) up to 1 MHz and stable phase shift up to 1.5 MHz.
    • Capacitive sensor achieved a sensitivity of 100 fF, with potential for 4 parallel measurements.
    • Platform supports sine, rectangular, and square wave signals with frequencies extendable up to 3.4 MHz.

    Conclusions:

    • The proposed platform offers a versatile and advanced solution for dielectrophoretic microfluidic applications and cell sensing.
    • The novel assembly technique ensures chip reusability, reducing costs and environmental impact.
    • This technology facilitates precise control and measurement in microfluidic systems.