化学
电化学发光
生物相容性
氯霉素
催化作用
猝灭(荧光)
电子转移
发光
纳米技术
生物传感器
荧光
组合化学
扩散
生物安全
电导率
细胞毒性
兴奋剂
检出限
作者
Jiangle Yi,Xue Dong,Yuanling Sun,Xueying Wang,Xuan Kuang,Yu Du,Hongmin Ma,Dawei Fan,Rui Feng,Qin Wei
标识
DOI:10.1021/acs.analchem.5c05369
摘要
High Resolution Image Download MS PowerPoint Slide Nanoconfinement strategy is an effective approach to solve the luminescence quenching of aggregation-induced emission (AIE) materials in dispersed states. However, conventional synthetic carriers mostly used excessive metal ions, resulting in significant defects in terms of biosafety. As a natural blood protein, hemoglobin (Hemo) exhibits excellent biocompatibility and contains Fe 2+, which can be used as a catalyst for electrochemiluminescence (ECL) process. Therefore, a novel self-catalytic aggregation-induced electronuminescence (AIECL) probe based on the confinement of tetrakis(4-aminophenyl)ethene (ETTA) by Hemo has been developed. It overcomes the high cytotoxicity of conventional synthetic carriers. In this work, Hemo was used as a dual-functional nanoencapsulant, which had dual roles as a nanoconfinement carrier and co-reaction promoter. Its unique quaternary structure not only provided a stable self-assembly environment for the nanoconfinement, but also effectively inhibited the free diffusion of ETTA in solution, thereby inducing the AIECL of ETTA. Importantly, Fe 2+ in Hemo could be used as co-reaction promoter to shorten the electron transfer pathway, while achieving self-catalytic and greatly enhancing the ECL performance of the luminophore. In addition, the coral-like Au structure could improve the conductivity and loading capacity of the electrode. The chloramphenicol sensor exhibited excellent detection performance with a low detection limit of 0.12 pM. This work provides new insight for constructing green and efficient biosafety probes, which have shown important application potential in the field of food safety testing.
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