Development of an integrated breath analysis technology for on-chip aerosol capture and molecular analysis

IF 2.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC Micro and Nano Engineering Pub Date : 2023-09-25 DOI:10.1016/j.mne.2023.100228

Filip Paeps , Thomas Degreef , Wout Duthoo , Yorick Koumans , Erik Emmen , Abdulkadir Yurt , Elisabeth Marchal , Andrey Kossarev , Thi-Minh-Tho Dam , Rabea Hanifa , Joost Van Duppen , Zhenxiang Luo , Marco Peca , Tobe Wauters , Wouter Vleugels , Nadia Chakrova , Johan Berte , Floris Vernieuwe , Maxime Delgrange , Hari Prasanth , Bert Verbruggen

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Abstract

As proven early on in the pandemic, SARS-CoV-2 is mainly transmitted by aerosols. This urged us to develop a silicon impactor that collects the virus particles directly from breath. Performing PCR on these breath samples proved equally sensitive as nasopharyngeal swabs during the first week of an infection [Stakenborg et al., 2022], yet it remained a mostly manual process and PCR turn-around-time was still long. To overcome these drawbacks, we developed a fast and sensitive, fully integrated point-of-need breath test, comprising a novel breath sampler device and PCR instrument. The breath sampler combines virus collection and in-situ RNA amplification. The PCR instrument performs very fast amplification of the released viral RNA. Sample-to-result time was reduced to <20 min with an equal performance as the original manual procedure.

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用于芯片气溶胶捕获和分子分析的集成呼吸分析技术的开发

正如疫情早期所证明的那样，严重急性呼吸系统综合征冠状病毒2型主要通过气溶胶传播。这促使我们开发一种直接从呼吸中收集病毒颗粒的硅冲击器。事实证明，在感染的第一周，对这些呼吸样本进行PCR与鼻咽拭子同样敏感[Stakenberg et al.，2022]，但这仍然是一个主要手动的过程，PCR的周转时间仍然很长。为了克服这些缺点，我们开发了一种快速灵敏、完全集成的需求点呼吸测试，包括一种新型的呼吸采样器和PCR仪器。呼吸采样器结合了病毒采集和原位RNA扩增。PCR仪器对释放的病毒RNA进行非常快速的扩增。样本到结果的时间减少到<；20分钟，性能与原始手动程序相同。

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