G. Nibudin, I. Tsiniaikin, G. Presnova, M. Rubtsova, A. Popov, P. Mikhailov, A. Trifonov, O. Snigirev, V. Krupenin, D. Presnov
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引用次数: 0
摘要
在这项工作中,我们介绍了一种基于纳米线通道场效应晶体管的生物传感器自动温度调节系统,该系统可全面控制生物分析所需的温度机制。系统元件包括带有纳米线通道的场效应晶体管、温度传感器和加热器,采用电子束光刻、反应离子蚀刻和高真空沉积技术在单个硅晶体上制造而成。已开发出用于控制和保持温度的 Unicue 电子元件。测量了温度计读数与加热功率的关系,这与数值模拟的结果十分吻合。对带有 PID 反馈的温度调节系统进行了演示,确保在 18 秒内将液体温度控制在 30-70 o C 范围内。使用合成单链 DNA(来自大肠杆菌的基因片段)演示了用于检测核酸的温度调节系统。在浓度为 3 fM 的样品中观察到了最小可检测反应。
THERMOREGULATION SYSTEM FOR BIOSENSORS BASED ON FIELD-EFFECT TRANSISTORS WITH A NANOWIRE CHANNEL
In this work we present an automatic thermoregulation system for biosensors based on field-effect transistors with a nanowire channel, which provides full control on the required temperature regime in bioanalytical analises. The system elements, including field-effect transistors with a nanowire channel, temperature sensors and heaters, were fabricated on a single silicon cristal using electron beam lithography, reactive ion etching and high-vacuum deposition techniques. Unicue electronics have been developed to control and maintain temperature. The dependence of thermometer readout on heating power was measured, which is in good agreement with the results of numerical simulation. A demonstration of a thermoregulation system with PID-feedback was carried out, ensuring the establishment of a desiered temperature in the range of 30-70◦ C in 18 s in liquid. A demonstration of a thermoregulation system for detecting nucleic acids was carried out using synthetic single-stranded DNA, which is a gene fragment from the bacterium Escherichia coli. The minimal detectable response was observed for a sample with a concentration of 3 fM.
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