Pan Yuxiang, Wan Zijian, Zhong Longjie, Li Xueqin, Wu Qi, Wang Jun, Wang Ping
Biosensor National Special Laboratory, Key Laboratory for Biomedical Engineering of Education Ministry, Department of Biomedical Engineering, Zhejiang University, Hangzhou, 310027, People's Republic of China.
State Key Laboratory of Transducer Technology, Chinese Academy of Sciences, Shanghai, 200050, People's Republic of China.
Biomed Microdevices. 2017 Jun;19(2):33. doi: 10.1007/s10544-017-0162-7.
Okadaic acid (OA) is a marine toxin ingested by shellfish. In this work, a simple, sensitive and label-free gap-based electrical competitive bioassay has been developed for this biotoxin detection. The gap-electrical biosensor is constructed by modifying interdigitated microelectrodes with gold nanoparticles (AuNPs) and using the self-catalytic growth of AuNPs as conductive bridges. In this development, the AuNPs growth is realized in the solution of glucose and chloroauric acid, with glucose oxidation used as the catalysis for growth of the AuNPs. The catalytic reaction product HO in turn reduces chloroauric acid to make the AuNPs grow. The conductance signal amplification is directly determined by the growth efficiency of AuNPs and closely related to the catalytic activity of AuNPs upon their interaction with OA molecule and OA aptamer. In the absence of OA molecule, the OA aptamer can absorb onto the surfaces of AuNPs due to electrostatic interaction, and the catalytically active sites of AuNPs are fully blocked. Thus the AuNPs growth would not happen. In contrast, the presence of OA molecule can hinder the interaction of OA aptamer and AuNPs. Then the AuNPs sites are exposed and the catalytic growth induces the conductance signal change. The results demonstrated that developed biosensor was able to specifically respond to OA ranging from 5 ppb to 80 ppb, providing limit of detection of 1 ppb. The strategy is confirmed to be effective for OA detection, which indicates the label-free OA biosensor has great potential to offer promising alternatives to the traditional analytical and immunological methods for OA detection.
冈田酸(OA)是一种贝类摄取的海洋毒素。在本研究中,已开发出一种用于检测这种生物毒素的简单、灵敏且无标记的基于间隙的电竞争生物测定法。间隙电生物传感器是通过用金纳米颗粒(AuNPs)修饰叉指微电极,并利用AuNPs的自催化生长作为导电桥构建而成。在这一过程中,AuNPs在葡萄糖和氯金酸溶液中生长,葡萄糖氧化用作AuNPs生长的催化剂。催化反应产物HO进而将氯金酸还原以使AuNPs生长。电导信号放大直接由AuNPs的生长效率决定,并与AuNPs与OA分子和OA适配体相互作用时的催化活性密切相关。在没有OA分子的情况下,OA适配体由于静电相互作用可吸附到AuNPs表面,AuNPs的催化活性位点被完全阻断。因此不会发生AuNPs生长。相反,OA分子的存在会阻碍OA适配体与AuNPs的相互作用。然后AuNPs位点被暴露,催化生长导致电导信号变化。结果表明,所开发的生物传感器能够特异性响应5 ppb至80 ppb的OA,检测限为1 ppb。该策略被证实对OA检测有效,这表明无标记的OA生物传感器有很大潜力为传统的OA检测分析和免疫方法提供有前景的替代方案。
