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Related Concept Videos

Flow Cytometry01:23

Flow Cytometry

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The development of flow cytometry techniques began in 1934 with initial attempts by Andrew Moldavan, a bacteriologist who counted the cells in a flowing capillary system. Moldavan pumped cells through a capillary tube focused under a microscope for visualization. The invention of photometry allowed the measurement of differentially-stained cells, and Louis Kamentsky developed the first multiparameter flow cytometer in 1965 to identify and count the cancer cells in cervical tissue specimens.
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System-on-Chip for Flow Cytometry With Impedance Measurement and Integrated Real-Time Size Classification.

Tzu-Hsuan Chou, Siyuan Yu, Calder Wilson

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    This summary is machine-generated.

    This study introduces an impedance measurement system-on-chip for cell counting. The device accurately determines cell size and counts particles in real-time using advanced signal processing and CMOS technology.

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    Area of Science:

    • Electrical Engineering
    • Biomedical Engineering
    • Microfluidics

    Background:

    • Flow cytometry is crucial for cell counting and analysis.
    • Accurate impedance measurements are key for label-free cell characterization.
    • Existing systems may lack real-time processing capabilities or require bulky instrumentation.

    Purpose of the Study:

    • To develop an integrated system-on-chip (SoC) for impedance-based flow cytometry.
    • To enable real-time cell counting and size determination.
    • To demonstrate the SoC's performance in particle detection and classification.

    Main Methods:

    • A source-differential, three-electrode sensing scheme in a microfluidic flow cell.
    • A front-end lock-in amplifier with a 60 MHz TIA, passive mixers, and low-pass filters.
    • Back-end processing with an 8-bit level-crossing ADC (LCADC) for I/Q signal digitization, feature extraction, and linear classification.
    • Fabrication in a 180 nm CMOS process.

    Main Results:

    • Achieved a noise floor of 733 fA/sqrt(Hz) and 23 pArms input-referred noise (1-1 kHz).
    • Demonstrated particle counting using polymer beads (3-10 µm diameters).
    • On-chip classification of 4.5 µm and 6 µm beads with 86.16% accuracy (offline) and 73.6% (real-time).

    Conclusions:

    • The developed SoC is effective for impedance-based flow cytometry applications.
    • The system enables real-time particle counting and size determination.
    • The integrated solution offers a promising approach for portable and efficient cell analysis systems.