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微滴微流控中的集成实时CMOS发光传感与阻抗谱分析

Integrated Real-Time CMOS Luminescence Sensing and Impedance Spectroscopy in Droplet Microfluidics.

作者信息

Liu Qijun, Mendoza Diana Arguijo, Yasar Alperen, Caygara Dilara, Kassem Aya, Densmore Douglas, Yazicigil Rabia Tugce

出版信息

IEEE Trans Biomed Circuits Syst. 2024 Dec;18(6):1233-1252. doi: 10.1109/TBCAS.2024.3491594. Epub 2024 Dec 9.

DOI:10.1109/TBCAS.2024.3491594
PMID:39509304
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11875993/
Abstract

High-throughput biosensor screening and optimization are critical for health and environmental monitoring applications to ensure rapid and accurate detection of biological and chemical targets. Traditional biosensor design and optimization methods involve labor-intensive processes, such as manual pipetting of large sample volumes, making them low throughput and inefficient for large-scale library screenings under various environmental and chemical conditions. We address these challenges by introducing a modular droplet microfluidic system embedded with custom CMOS integrated circuits (ICs) for impedance spectroscopy and bioluminescence detection. Fabricated in a 65 nm process, our CMOS ICs enable efficient droplet detection and analysis. We demonstrate successful sensing of luciferase enzyme-substrate reactions in nL-volume droplets. The impedance spectroscopy chip detects 4 nL droplets at 67 mm/s with a 45 pA resolution, while the luminescence detector senses optical signals from 38 nL droplets with a 6.7 nA/count resolution. We show real-time concurrent use of both detection methods within our hybrid platform for cross-validation. This system greatly advances conventional biosensor testing by increasing flexibility, scalability, and cost-efficiency.

摘要

高通量生物传感器筛选和优化对于健康与环境监测应用至关重要,以确保对生物和化学目标进行快速准确的检测。传统的生物传感器设计和优化方法涉及劳动密集型过程,如手动移取大量样品,这使得它们在各种环境和化学条件下进行大规模文库筛选时通量低且效率低下。我们通过引入一种嵌入定制CMOS集成电路(IC)的模块化液滴微流控系统来解决这些挑战,该系统用于阻抗谱和生物发光检测。我们的CMOS IC采用65纳米工艺制造,能够实现高效的液滴检测和分析。我们展示了在纳升体积的液滴中成功检测荧光素酶-底物反应。阻抗谱芯片以45皮安的分辨率在67毫米/秒的速度下检测4纳升的液滴,而发光探测器以6.7纳安/计数的分辨率感测来自38纳升液滴的光信号。我们展示了在我们的混合平台中同时实时使用这两种检测方法进行交叉验证。该系统通过提高灵活性、可扩展性和成本效益,极大地推动了传统生物传感器测试的发展。

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