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四通道超声波传感器,用于散装液体和生物化学表面探测。

Four-Channel Ultrasonic Sensor for Bulk Liquid and Biochemical Surface Interrogation.

机构信息

Panevėžys Faculty of Technology and Business, Kaunas University of Technology, 37164 Panevėžys, Lithuania.

出版信息

Biosensors (Basel). 2024 Jan 26;14(2):66. doi: 10.3390/bios14020066.

DOI:10.3390/bios14020066
PMID:38391985
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10887170/
Abstract

Custom electronics tailored for ultrasonic applications with four ultrasonic transmit-receive channels and a nominal 25 MHz single channel frequency were developed for ultrasound BAW and SAW biosensor uses. The designed integrated microcontroller, supported by Python with a SciPy library, and the developed system measured the time of flight (TOF) and other wave properties to characterize the acoustic properties of a bulk of the liquid in a microchannel or acoustic properties of biological species attached to an analytic surface in real time. The system can utilize both piezoelectric and capacitive micromachined ultrasound transducers. The device demonstrated a linear response to changes in water salinity. This response was primarily attributed to the time-of-flight (TOF) changes related to the varying solution density. Furthermore, real-time DNA oligonucleotide-based interactions between oligonucleotides immobilized on the device's analytical area and oligonucleotides attached to gold nanoparticles (Au NPs) in the solution were demonstrated. The biological interaction led to an exponential decrease in the acoustic interfacial wave propagating across the interface between the solution and the solid surface of the sensor, the TOF signal. This decrease was attributed to the increase in the effective density of the solution in the vicinity of the sensor's analytical area, as Au NPs modified by oligonucleotides were binding to the analytical area. The utilization of Au NPs in oligonucleotide surface binding yields a considerably stronger sensor signal than previously observed in earlier CMUT-based TOF biosensor prototypes.

摘要

专为超声应用定制的定制电子产品,具有四个超声发射-接收通道和一个标称 25MHz 的单通道频率,用于超声 BAW 和 SAW 生物传感器用途。设计的集成微控制器由 Python 支持,带有 SciPy 库,开发的系统测量飞行时间 (TOF) 和其他波特性,以实时表征微通道中液体的体积的声特性或附着在分析表面上的生物物质的声特性。该系统可以同时利用压电和电容式微加工超声换能器。该设备对水盐度的变化表现出线性响应。这种响应主要归因于与溶液密度变化相关的飞行时间 (TOF) 变化。此外,还证明了设备分析区域上固定的寡核苷酸与溶液中金纳米粒子 (Au NPs) 之间实时基于 DNA 寡核苷酸的相互作用。生物相互作用导致在溶液和传感器的固体表面之间传播的声界面波的传播时间 (TOF) 信号呈指数下降。这种减少归因于传感器分析区域附近溶液的有效密度增加,因为寡核苷酸修饰的 Au NPs 与分析区域结合。在寡核苷酸表面结合中使用 Au NPs 可产生比以前在基于 CMUT 的 TOF 生物传感器原型中观察到的强得多的传感器信号。

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