Caifeng Ding scite author profile

A novel and sensitive flow injection chemiluminescence assay for sequence-specific DNA detection based on signal amplification with nanoparticles (NPs) is reported in the present work. The "sandwich-type" DNA biosensor was fabricated with the thiol-functionalized capture DNA first immobilized on an Au electrode and hybridized with one end of target DNA, the other end of which was recognized with a signal DNA probe labeled with CuS NPs and Au NPs on the 3'- and 5'-terminus, respectively. The hybridization events were monitored by the CL intensity of luminol-H2O2-Cu(2+) after the cupric ions were dissolved from the hybrids. We demonstrated that the incorporation of Au NPs in this sensor design significantly enhanced the sensitivity and the selectivity because a single Au NP can be loaded with hundreds of signal DNA probe strands, which were modified with CuS NPs. The ratios of Au NPs, signal DNA probes, and CuS NPs modified on the gold electrode were approximately 1/101/103. A preconcentration process of cupric ions performed by anodic stripping voltammetry technology further increased the sensor performance. As a result of these two combined effects, this DNA sensor could detect as low as femtomolar target DNA and exhibited excellent selectivity against two-base mismatched DNA. Under the optimum conditions, the CL intensity was increased with the increase of the concentration of target DNA in the range of 2.0 x 10(-14)-2.0 x 10(-12) M. A detection limit of 4.8 x 10(-15) M target DNA was achieved.

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Electrochemical Biosensor with Enhanced Antifouling Capability for COVID-19 Nucleic Acid Detection in Complex Biological Media

Song

Chen

et al. 2021

Anal. Chem.

119

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Biofouling caused by the accumulation of biomolecules on sensing surfaces is one of the major problems and challenges to realize the practical application of electrochemical biosensors, and an effective way to counter this problem is the construction of antifouling biosensors. Herein, an antifouling electrochemical biosensor was constructed based on electropolymerized polyaniline (PANI) nanowires and newly designed peptides for the detection of the COVID-19 N-gene. The inverted Y-shaped peptides were designed with excellent antifouling properties and two anchoring branches, and their antifouling performances against proteins and complex biological media were investigated using different approaches. Based on the biotin–streptavidin affinity system, biotin-labeled probes specific to the N-gene (nucleocapsid phosphoprotein) of COVID-19 were immobilized onto the peptide-coated PANI nanowires, forming a highly sensitive and antifouling electrochemical sensing interface for the detection of COVID-19 nucleic acid. The antifouling genosensor demonstrated a wide linear range (10 –14 to 10 –9 M) and an exceptional low detection limit (3.5 fM). The remarkable performance of the genosensor derives from the high peak current of PANI, which is chosen as the sensing signal, and the extraordinary antifouling properties of designed peptides, which guarantee accurate detection in complex systems. These crucial features represent essential elements for future rapid and decentralized clinical testing.

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Photolysis of glyoxal at 193, 248, 308 and 351 nm

Zhu

Kellis

Ding

1996

Chemical Physics Letters

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Fluorescence Detection of Telomerase Activity in Cancer Cells Based on Isothermal Circular Strand-Displacement Polymerization Reaction

Ding

et al. 2010

Anal. Chem.

100

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On the basis of the extension reaction of a telomerase substrate (TS) primer in the presence of the telomerase, the inherent signal-transduction mechanism of the hairpin fluorescence probe, and the strand-displacement property of polymerase, an amplified fluorescence detection of telomerase activity in the cancer cells was described in this manuscript. A hairpin fluorescence probe was used as not only the fluorescence signal carrier but also a template of the telomere elongation reaction. In the presence of the telomerase, the stems of the hairpin probes were opened and the telomerase activity could be determined with the fluorescence enhancement. The telomerase activity in the HeLa extracts equivalent to 40-1000 cells was detected by this method, with the multiple rounds of isothermal strand replication, which led to strand displacement, and constituted consecutive signal amplification for the novel detection paradigm that allowed measurement of telomerase activity in crude cell extracts equivalent to 4 cultured HeLa cells. Using magnetic beads as both the separation tool and the immobilization matrix of the aptamer of Ramos cells (CRL-1596, B-cell, human Burkitt's lymphoma), the detection of the amount of the Ramos cell with the low concentration of 100 cells mL(-1) confirmed the reliability and practicality of the protocol, which reveal a good prospect of this platform for analysis.

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Caifeng Ding

Ultrasensitive Flow Injection Chemiluminescence Detection of DNA Hybridization Using Signal DNA Probe Modified with Au and CuS Nanoparticles

Electrochemical Biosensor with Enhanced Antifouling Capability for COVID-19 Nucleic Acid Detection in Complex Biological Media

Photolysis of glyoxal at 193, 248, 308 and 351 nm

Fluorescence Detection of Telomerase Activity in Cancer Cells Based on Isothermal Circular Strand-Displacement Polymerization Reaction

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