人人共享的片上实验室:介绍一种使用标准CMOS工艺进行多参数生物传感的电子光子平台

Christos Adamopoulos;Panagiotis Zarkos;Sidney Buchbinder;Pavan Bhargava;Ali Niknejad;Mekhail Anwar;Vladimir Stojanović
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引用次数: 6

摘要

最近的疫情表明,关于各种感染的准确和按需信息需要高度通用的护理点(PoC)平台,为每位患者提供个性化的诊断和预后多参数信息。尽管过去几年在各种生物传感技术方面取得了重大进展,但现有的解决方案无法满足高度可扩展和便携式下一代PoC设备所需的功率和面积要求。这项工作提出了一种基于零变化大体积CMOS-SOI工艺中第一个完全集成的电子光子平台的解决方案,该解决方案针对分子和超声传感应用而定制。利用$10\mu\text{m}$微环谐振器(MRR)与片上电子器件的共同集成,我们通过在单片电子片上光子系统(EPSoC)上提供纳米光子传感和读出处理来满足当前对可扩展性、功率和面积的需求。这项工作打开了通往完整和独立的芯片实验室(LoC)系统的大门,该系统能够提供多参数生物传感信息。
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Lab-on-Chip for Everyone: Introducing an Electronic-Photonic Platform for Multiparametric Biosensing Using Standard CMOS Processes
The recent pandemic has shown that accurate and on-demand information on various infections requires highly versatile, Point-of-Care (PoC) platforms providing diagnostic and prognostic multiparametric information, personalized to each patient. Despite the significant progress made over the last years in various biosensing technologies, existing solutions fail to meet the power and area requirements needed for highly scalable and portable next-generation PoC devices. This work presents a solution based on a first of its kind fully integrated electronic-photonic platform in a zero-change high volume CMOS-SOI process, tailored towards molecular and ultrasound sensing applications. Leveraging co-integration of $10\mu \text{m}$ micro-ring resonators (MRRs) with on-chip electronics, we address the current needs of scalability, power and area by providing nanophotonic sensing and readout processing on a monolithic electronic-photonic system-on-chip (EPSoC). This work unlocks the door towards complete and self-contained Lab-on-Chip (LoC) systems, capable of providing multiparametric biosensing information.
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