Bin‐Cheng Yin scite author profile

Traditional molecular beacons, widely applied for detection of nucleic acids, have an intrinsic limitation on sensitivity, as one target molecule converts only one beacon molecule to its fluorescent form. Herein, we take advantage of the duplex-specific nuclease (DSN) to create a new signal-amplifying mechanism, duplex-specific nuclease signal amplification (DSNSA), to increase the detection sensitivity of molecular beacons (Taqman probes). DSN nuclease is employed to recycle the process of target-assisted digestion of Taqman probes, thus, resulting in a significant fluorescence signal amplification through which one target molecule cleaves thousands of probe molecules. We further demonstrate the efficiency of this DSNSA strategy for rapid direct quantification of multiple miRNAs in biological samples. Our experimental results showed a quantitative measurement of sequence-specific miRNAs with the detection limit in the femtomolar range, nearly 5 orders of magnitude lower than that of conventional molecular beacons. This amplification strategy also demonstrated a high selectivity for discriminating differences between miRNA family members. Considering the superior sensitivity and specificity, as well as the multiplex and simple-to-implement features, this method promises a great potential of becoming a routine tool for simultaneously quantitative analysis of multiple miRNAs in tissues or cells, and supplies valuable information for biomedical research and clinical early diagnosis.

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Highly Sensitive Detection of Mercury(II) Ions by Fluorescence Polarization Enhanced by Gold Nanoparticles

Yin

2008

Angew Chem Int Ed

369

201

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Rational Engineering of a Dynamic, Entropy‐Driven DNA Nanomachine for Intracellular MicroRNA Imaging

et al. 2017

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We rationally engineered an elegant entropy-driven DNA nanomachine with three-dimensional track and applied it for intracellular miRNAs imaging. The proposed nanomachine is activated by target miRNA binding to drive a walking leg tethered to gold nanoparticle with a high density of DNA substrates. The autonomous and progressive walk on the DNA track via the entropy-driven catalytic reaction of intramolecular toehold-mediated strand migration leads to continuous disassembly of DNA substrates, accompanied by the recovery of fluorescence signal due to the specific release of a dye-labeled substrate from DNA track. Our nanomachine outperforms the conventional intermolecular reaction-based gold nanoparticle design in the context of an improved sensitivity and kinetics, attributed to the enhanced local effective concentrations of working DNA components from the proximity-induced intramolecular reaction. Moreover, the nanomachine was applied for miRNA imaging inside living cells.

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Interaction of peptides with graphene oxide and its application for real-time monitoring of protease activity

et al. 2011

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Attomolar Ultrasensitive MicroRNA Detection by DNA-Scaffolded Silver-Nanocluster Probe Based on Isothermal Amplification

et al. 2012

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MicroRNAs (miRNAs) play vital roles in a plethora of biological and cellular processes. The levels of miRNAs can be useful biomarkers for cellular events or disease diagnosis, thus the method for sensitive and selective detection of miRNAs is imperative to miRNA discovery, study, and clinical diagnosis. Here we develop a novel method to quantify miRNA expression levels as low as attomolar sensitivity by target-assisted isothermal exponential amplification coupled with fluorescent DNA-scaffolded AgNCs and demonstrated its feasibility in the application of detecting miRNA in real samples. The method reveals superior sensitivity with a detection limit of miRNA of 2 aM synthetic spike-in target miRNA under pure conditions (approximately 15 copies of a miRNA molecule in a volume of 10 μL) and can detect at least a 10 aM spike-in target miRNA in cell lysates. The method also shows the high selectivity for discriminating differences between miRNA family members, thus providing a promising alternative to standard approaches for quantitative detection of miRNA. This simple and cost-effective strategy has a potential of becoming the major tool for simultaneous quantitative analysis of multiple miRNAs (biomarkers) in tissues or cells and supplies valuable information for biomedical research and clinical early diagnosis.

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Bin‐Cheng Yin

One-Step, Multiplexed Fluorescence Detection of microRNAs Based on Duplex-Specific Nuclease Signal Amplification

Highly Sensitive Detection of Mercury(II) Ions by Fluorescence Polarization Enhanced by Gold Nanoparticles

Rational Engineering of a Dynamic, Entropy‐Driven DNA Nanomachine for Intracellular MicroRNA Imaging

Interaction of peptides with graphene oxide and its application for real-time monitoring of protease activity

Attomolar Ultrasensitive MicroRNA Detection by DNA-Scaffolded Silver-Nanocluster Probe Based on Isothermal Amplification

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