Collaborative Innovation Center for Green Chemical Manufacturing and Accurate Detection, Key Laboratory of Interfacial Reaction & Sensing Analysis in Universities of Shandong, University of Jinan, Jinan 250022, Shandong, China.
School of Information Science and Engineering, University of Jinan, Jinan 250022, China.
Anal Chem. 2021 Oct 26;93(42):14196-14203. doi: 10.1021/acs.analchem.1c02922. Epub 2021 Oct 12.
Interesting double-channel microfluidic chip integration with a sandwich-type cathodic photo-electrochemical (PEC) biosensor is utilized for ultrasensitive and efficient detection of cardiac troponin I (cTnI) based on a signal amplification strategy. The Pd nanoparticles loading on the I-doped bismuth oxybromide with oxygen vacancies (Pd/I:BiOBr-OVs) as a sensing platform can effectively enhance cathodic photocurrent response by improving the visible light absorption ability with I doping, facilitating the efficiency separation of photogenerated electron-hole pairs with OVs, and increasing the electron-transfer rate with Pd loading, where the photogenerated electron could be captured by dissolved O to boost generation of a superoxide anion radical (O). To further enhance the PEC response, a novel superoxide dismutase loaded on gold@polyaniline (SOD-Au@PANI) as a signal amplification label is developed for incubating the detection antibody (dAb). It is particularly noteworthy that SOD can effectively catalyze dismutation of the O to produce HO and O, and Au@PANI with a good reduction and catalytic property can catalyze the produced HO into HO and O. Then, the produced O that has been dissolved or adsorbed can capture more photogenerated electrons, resulting in more electron-hole pairs to separate, so as to the cathodic photocurrent signal of this system which can be amplified more significantly. Therefore, a signal amplification cathodic PEC biosensor is prepared for sensitively detecting cTnI, in which a good linearity ranging from 0.1 pg/mL to 100 ng/mL with a low detection limit of 0.042 pg/mL is obtained. Furthermore, the proposed biosensor exhibits excellent sensitivity and high selectivity, which could be extended to detect other disease markers in biological analysis and early disease diagnosis.
利用具有夹心型阴极光电化学(PEC)生物传感器的双通道微流控芯片进行有趣的集成,基于信号放大策略,实现了对心脏型肌钙蛋白 I(cTnI)的超灵敏和高效检测。将 Pd 纳米粒子负载在具有氧空位的掺碘铋氧溴(Pd/I:BiOBr-OVs)上作为传感平台,通过 I 掺杂提高可见光吸收能力,促进光生电子-空穴对的有效分离,以及通过 Pd 负载增加电子转移速率,从而有效增强阴极光电流响应,其中光生电子可以被溶解氧捕获,从而促进超氧阴离子自由基(O)的生成。为了进一步增强 PEC 响应,开发了一种新型的超氧化物歧化酶负载在金@聚苯胺(SOD-Au@PANI)上作为信号放大标记,用于孵育检测抗体(dAb)。特别值得注意的是,SOD 可以有效地催化 O 的歧化反应,生成 HO 和 O,而具有良好还原和催化性能的 Au@PANI 可以催化产生的 HO 进一步转化为 HO 和 O。然后,溶解或吸附的 O 可以捕获更多的光生电子,从而产生更多的电子-空穴对分离,从而使该系统的阴极光电流信号得到更显著的放大。因此,制备了一种信号放大的阴极 PEC 生物传感器,用于灵敏地检测 cTnI,该传感器在 0.1 pg/mL 至 100 ng/mL 的宽线性范围内具有低至 0.042 pg/mL 的检测限。此外,该生物传感器表现出优异的灵敏度和高选择性,可扩展用于生物分析和早期疾病诊断中检测其他疾病标志物。
