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Real-time reliable determination of binding kinetics of DNA hybridization using a multi-channel graphene biosensor.


ABSTRACT: Reliable determination of binding kinetics and affinity of DNA hybridization and single-base mismatches plays an essential role in systems biology, personalized and precision medicine. The standard tools are optical-based sensors that are difficult to operate in low cost and to miniaturize for high-throughput measurement. Biosensors based on nanowire field-effect transistors have been developed, but reliable and cost-effective fabrication remains a challenge. Here, we demonstrate that a graphene single-crystal domain patterned into multiple channels can measure time- and concentration-dependent DNA hybridization kinetics and affinity reliably and sensitively, with a detection limit of 10?pM for DNA. It can distinguish single-base mutations quantitatively in real time. An analytical model is developed to estimate probe density, efficiency of hybridization and the maximum sensor response. The results suggest a promising future for cost-effective, high-throughput screening of drug candidates, genetic variations and disease biomarkers by using an integrated, miniaturized, all-electrical multiplexed, graphene-based DNA array.

SUBMITTER: Xu S 

PROVIDER: S-EPMC5364407 | biostudies-literature | 2017 Mar

REPOSITORIES: biostudies-literature

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Real-time reliable determination of binding kinetics of DNA hybridization using a multi-channel graphene biosensor.

Xu Shicai S   Zhan Jian J   Man Baoyuan B   Jiang Shouzhen S   Yue Weiwei W   Gao Shoubao S   Guo Chengang C   Liu Hanping H   Li Zhenhua Z   Wang Jihua J   Zhou Yaoqi Y  

Nature communications 20170321


Reliable determination of binding kinetics and affinity of DNA hybridization and single-base mismatches plays an essential role in systems biology, personalized and precision medicine. The standard tools are optical-based sensors that are difficult to operate in low cost and to miniaturize for high-throughput measurement. Biosensors based on nanowire field-effect transistors have been developed, but reliable and cost-effective fabrication remains a challenge. Here, we demonstrate that a graphene  ...[more]

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