A DNA biosensor integrating surface hybridization, thermo-responsive coating, laminar-flow technology and localized photothermal effect for efficient electrochemical detection of nucleic acids†

IF 3.5 Q2 CHEMISTRY, ANALYTICAL Sensors & diagnostics Pub Date : 2024-10-14 DOI:10.1039/D4SD00288A

Ludovica Maugeri, Giorgia Fangano, Angelo Ferlazzo, Giuseppe Forte, Antonino Gulino and Salvatore Petralia

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Abstract

A hybrid electrochemical DNA biosensor that integrates various technologies, such as laminar flow, surface hybridization, DNA-microarray, thermo-responsive nanocoating and localized photothermal heating, is presented here. A photothermal module based on gold nanostructures photoactivated by a green-light source (532 nm) was developed for easy temperature management. The hybridization product is electrochemically detected by a three-planar-microelectrode system upon dsDNA denaturation. Performances of the hybrid biosensor were investigated by detection of the cDNA target, resulting in a sensitivity of about 2.62 μA nM⁻¹ cm⁻² and a limit of detection of 1.5 nM, as a function of the capture probe sequence. The findings facilitate the integration of multiple technologies, enabling the development of low-cost and point-of-care detection systems for molecular analysis.

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结合表面杂交、热响应涂层、层流技术和局部光热效应的DNA生物传感器用于核酸的高效电化学检测†

本文介绍了一种集成了层流、表面杂交、DNA微阵列、热响应纳米涂层和局部光热加热等多种技术的混合电化学DNA生物传感器。利用绿光源（532 nm）光激活金纳米结构，研制了一种易于温度管理的光热模块。在dsDNA变性过程中，用三平面微电极系统对杂交产物进行了电化学检测。通过对cDNA靶点的检测，检测灵敏度约为2.62 μA nM−1 cm−2，检测限为1.5 nM，与捕获探针序列有关。这些发现促进了多种技术的整合，使低成本和即时检测系统的开发成为可能，用于分子分析。

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来源期刊

Sensors & diagnostics

CiteScore

2.30

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0.00%

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