Extended-gate field-effect transistor chemo- and biosensors: State of the art and perspectives

Next Nanotechnology Pub Date : 2023-09-01 DOI:10.1016/j.nxnano.2023.100025

Željko Janićijević , Trang-Anh Nguyen-Le , Larysa Baraban

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Abstract

Extended-gate field-effect transistor (EG-FET) chemo- and biosensors are emerging tools for a wide range of biomedical applications. Significant efforts have been made to make them ultrasensitive to biomolecules via the development of miniaturized sensing transistors, design and optimization of extended gate sensing layer, exploration of the multiplexing ability of EG-FET configuration, and advanced data analysis. Here, we specifically focus on several important aspects related to the construction and current applications of EG-FET sensors. Namely, we review the materials, fabrication, properties of the transducer, specificities of the conditioning electronics, and signal analysis. At the same time, we discuss the current drawbacks of these sensors preventing their straightforward commercialization, such as output signal variation and non-linearities of the response. We also review the recent key applications of EG-FET sensors in the areas of early medical diagnostics, ecology, food and chemical industries, and others. Finally, we briefly discuss the future perspectives in the development of this class of sensors.

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扩展栅场效应晶体管化学与生物传感器:现状与展望

扩展栅场效应晶体管(EG-FET)化学和生物传感器是广泛应用于生物医学的新兴工具。通过开发小型化传感晶体管，设计和优化扩展栅极传感层，探索EG-FET结构的多路复用能力以及先进的数据分析，为使其对生物分子超敏感做出了重大努力。在这里，我们特别关注与EG-FET传感器的结构和当前应用相关的几个重要方面。也就是说，我们回顾了材料，制造，换能器的特性，调节电子的特性和信号分析。同时，我们讨论了这些传感器目前的缺点，如输出信号的变化和响应的非线性，阻碍了它们的直接商业化。我们还综述了近年来eeg - fet传感器在早期医学诊断、生态、食品和化学工业等领域的主要应用。最后，我们简要讨论了这类传感器的未来发展前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Next Nanotechnology

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