Versatile digital polymerase chain reaction chip design, fabrication, and image processing

Huanan Li; Haoqing Zhang; Ying Xu; Alzbeta Tureckova; Pavel Zahradník; Honglong Chang; Pavel Neuzil

doi:10.1016/j.snb.2018.12.072

Versatile digital polymerase chain reaction chip design, fabrication, and image processing

Huanan Li, Haoqing Zhang, Ying Xu, Alzbeta Tureckova, Pavel Zahradník, Honglong Chang, Pavel Neuzil

机电学院

科研成果: 期刊稿件 › 文章 › 同行评审

36 引用（Scopus）

摘要

We present a family of digital polymerase chain reaction (dPCR) chips made of silicon that are (9 × 9) mm² in size, have a unique layout design, and have between 26,448 and 1,656,000 reaction wells. The chip layout was split into six fields sized 4200 × 2785 μm² that contain reaction wells with a gap of a few μm separating the fields from each other. We also developed a universal fluorescence imaging method capable of processing images from those chips. It comprised automatic image acquisition, image stitching, alignment mark registration, rotation correction, determination of reaction wells’ positions, and result processing. The chip design, with fully automated image processing, provided a fast and reliable system for the absolute quantitative analysis of dPCR. Combined with ease-of-use, this family of dPCR chips offers a pathway to enable fast and affordable digital microfluidic diagnostic applications.

源语言	英语
页（从-至）	677-684
页数	8
期刊	Sensors and Actuators, B: Chemical
卷	283
DOI	https://doi.org/10.1016/j.snb.2018.12.072
出版状态	已出版 - 15 3月 2019

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author = "Huanan Li and Haoqing Zhang and Ying Xu and Alzbeta Tureckova and Pavel Zahradn{\'i}k and Honglong Chang and Pavel Neuzil",

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AU - Li, Huanan

AU - Zhang, Haoqing

AU - Xu, Ying

AU - Tureckova, Alzbeta

AU - Zahradník, Pavel

AU - Chang, Honglong

AU - Neuzil, Pavel

PY - 2019/3/15

Y1 - 2019/3/15

N2 - We present a family of digital polymerase chain reaction (dPCR) chips made of silicon that are (9 × 9) mm2 in size, have a unique layout design, and have between 26,448 and 1,656,000 reaction wells. The chip layout was split into six fields sized 4200 × 2785 μm2 that contain reaction wells with a gap of a few μm separating the fields from each other. We also developed a universal fluorescence imaging method capable of processing images from those chips. It comprised automatic image acquisition, image stitching, alignment mark registration, rotation correction, determination of reaction wells’ positions, and result processing. The chip design, with fully automated image processing, provided a fast and reliable system for the absolute quantitative analysis of dPCR. Combined with ease-of-use, this family of dPCR chips offers a pathway to enable fast and affordable digital microfluidic diagnostic applications.

AB - We present a family of digital polymerase chain reaction (dPCR) chips made of silicon that are (9 × 9) mm2 in size, have a unique layout design, and have between 26,448 and 1,656,000 reaction wells. The chip layout was split into six fields sized 4200 × 2785 μm2 that contain reaction wells with a gap of a few μm separating the fields from each other. We also developed a universal fluorescence imaging method capable of processing images from those chips. It comprised automatic image acquisition, image stitching, alignment mark registration, rotation correction, determination of reaction wells’ positions, and result processing. The chip design, with fully automated image processing, provided a fast and reliable system for the absolute quantitative analysis of dPCR. Combined with ease-of-use, this family of dPCR chips offers a pathway to enable fast and affordable digital microfluidic diagnostic applications.

KW - Array

KW - Digital PCR

KW - DNA counting

KW - Fluorescence image analysis

KW - Microfluidic chip

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Versatile digital polymerase chain reaction chip design, fabrication, and image processing

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