半导体
适体
材料科学
纳米技术
光电流
生物传感器
DNA
合理设计
光电子学
放大器
电子
微泡
小分子
信号(编程语言)
检出限
分子
密度泛函理论
载流子
外体
量子点
共价键
光电化学
半导体器件
晶体管阵列
电极
有机半导体
化学物理
微流控
生物分子
跟踪(教育)
A-DNA
生物物理学
作者
Huajuan Ye,Jinfa Chen,X. K. Lv,Wenxin Wu,Zhenli Qiu,Jiyu He,Dawei Fan,Ning Li,Bin Han,Junyang Zhuang
标识
DOI:10.1021/acsami.5c15876
摘要
The development of photoelectrochemical (PEC) biosensors with enhanced sensitivity and structural simplicity remains a key challenge in biomolecular detection. In this work, we report an unexpected and previously overlooked phenomenon in which DNA aptamers inherently act as amplifiers of PEC signals at semiconductor interfaces. Traditionally regarded solely as passive recognition elements, DNA aptamers─exemplified by the EpCAM-specific SYL3C─were found to markedly increase photocurrent when assembled on graphitic carbon nitride (g-C3N4)-based PEC electrodes. To further enhance interfacial charge transfer, g-C3N4 was covalently functionalized with 1,3,5-benzenetricarboxaldehyde (BTA), forming a donor-acceptor structured semiconductor (g-C3N4-BTA). Density functional theory (DFT) calculations and Mott-Schottky analysis revealed that the lowest unoccupied molecular orbital (LUMO) levels of DNA bases are positioned above the conduction band (CB) edges of both g-C3N4 and g-C3N4-BTA, enabling thermodynamically favorable injection of photoexcited electrons from DNA molecules into the semiconductor CB. This interfacial electron injection, analogous to dye-sensitized solar cells, accounts for the observed PEC signal amplification. Based on this mechanistic understanding, we developed a SYL3C/AuNPs/chitosan/g-C3N4-BTA-modified electrode for ultrasensitive detection of EpCAM-positive exosomes, achieving a detection limit of 988 particles mL-1. Furthermore, the sensor demonstrated robust performance in monitoring phenotypic changes of exosomes secreted by HepG2 cells in response to chemotherapy drug treatment, highlighting its potential for functional exosome analysis in cancer research. This study not only identifies a previously unrecognized inherent property of DNA aptamers to enhance semiconductor photoactivity, but also establishes a minimalist and broadly applicable design principle for constructing high-performance PEC biosensors. The mechanistic insights presented here open new avenues for the rational design of PEC sensing interfaces and extend the utility of DNA aptamers beyond molecular recognition toward active signal amplification.
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