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An Oligonucleotide‐Distortion‐Responsive Organic Transistor for Platinum‐Drug‐Induced DNA‐Damage Detection

Dekai Ye, Juan Wang, Hongguang Shen, Xinping Feng, Lanyi Xiang, Wen‐Long Jin, Wenrui Zhao, Jiamin Ding, Zihan He, Ye Zou, Qing Meng, Wei Cui, Fengjiao Zhang, Chong‐an Di, Chunhai Fan, Daoben Zhu

2021Advanced Materials16 citationsDOI

Abstract

Abstract Organic transistor with DNA‐damage evaluation ability can open up novel opportunities for bioelectronic devices. Even though trace amounts of drugs can cause cumulative gene damage in vivo, the extremely low occurrence proportion makes them hardly transduced into detectable electric signals. Here, an ultrasensitive DNA‐damage sensor based on an oligonucleotide‐distortion‐responsive organic transistor (DROT) is reported by creating controllable conformation change of double‐stranded DNA on the surface of organic semiconductors. In combination with interfacial charge redistribution and efficient signal amplification, the DROT provides an ultrasensitive single‐site DNA‐damage response with 20.5 s even upon 1 × 10 −12 m cisplatin. The high generalizability of this DROT to three generations of classical platinum drugs and gene‐relevant DNA damage is demonstrated. A biochip is further designed for intelligent damage analysis in complex environments, which holds the potential for high‐throughput biotoxicity evaluation and drug screening in the future.

Topics & Concepts

Materials scienceTransistorDNA damageNanotechnologyDNAOligonucleotidePlatinumBiosensorChemistryBiochemistryVoltageCatalysisQuantum mechanicsPhysicsOrganic Electronics and PhotovoltaicsConducting polymers and applicationsAdvanced biosensing and bioanalysis techniques
An Oligonucleotide‐Distortion‐Responsive Organic Transistor for Platinum‐Drug‐Induced DNA‐Damage Detection | Litcius