Your search keyword '"Wang, Zhenxing"' showing total 3 results

1. Point Decoration of Silicon Nanowires: An Approach Toward Single‐Molecule Electrical Detection.

Author

Wang, Jindong, Shen, Fangxia, Wang, Zhenxing, He, Gen, Qin, Jinwen, Cheng, Nongyi, Yao, Maosheng, Li, Lidong, and Guo, Xuefeng

Abstract

Probing interactions of biological systems at the molecular level is of great importance to fundamental biology, diagnosis, and drug discovery. A rational bioassay design of lithographically integrating individual point scattering sites into electrical circuits is capable of realizing real‐time, label‐free biodetection of influenza H1N1 viruses with single‐molecule sensitivity and high selectivity by using silicon nanowires as local reporters in combination with microfluidics. This nanocircuit‐based architecture is complementary to more conventional optical techniques, but has the advantages of no bleaching problems and no fluorescent labeling. These advantages offer a promising platform for exploring dynamics of stochastic processes in biological systems and gaining information from genomics to proteomics to improve accurate molecular and even point‐of‐care clinical diagnosis.A bioassay design involving lithographically integrating point scattering sites into electrical circuits is capable of realizing real‐time, label‐free biodetection of H1N1 viruses with single‐molecule sensitivity and high selectivity by using Si nanowires as local reporters in combination with microfluidics. This architecture is complementary to conventional optical techniques but has the advantages of no bleaching or fluorescent labeling. [ABSTRACT FROM AUTHOR]

Published

2014

2. Point Decoration of Silicon Nanowires: An Approach Toward Single-Molecule Electrical Detection.

Author

Wang, Jindong, Shen, Fangxia, Wang, Zhenxing, He, Gen, Qin, Jinwen, Cheng, Nongyi, Yao, Maosheng, Li, Lidong, and Guo, Xuefeng

Subjects

*ELECTRIC circuits, *H1N1 influenza, *BIOLOGICAL assay, *SILICON nanowires, *MICROFLUIDICS, *STOCHASTIC processes, *PROTEOMICS

Abstract

Probing interactions of biological systems at the molecular level is of great importance to fundamental biology, diagnosis, and drug discovery. A rational bioassay design of lithographically integrating individual point scattering sites into electrical circuits is capable of realizing real-time, label-free biodetection of influenza H1N1 viruses with single-molecule sensitivity and high selectivity by using silicon nanowires as local reporters in combination with microfluidics. This nanocircuit-based architecture is complementary to more conventional optical techniques, but has the advantages of no bleaching problems and no fluorescent labeling. These advantages offer a promising platform for exploring dynamics of stochastic processes in biological systems and gaining information from genomics to proteomics to improve accurate molecular and even point-of-care clinical diagnosis. [ABSTRACT FROM AUTHOR]

Published

2014

3. Frontispiece: Point Decoration of Silicon Nanowires: An Approach Toward Single-Molecule Electrical Detection.

Author

Wang, Jindong, Shen, Fangxia, Wang, Zhenxing, He, Gen, Qin, Jinwen, Cheng, Nongyi, Yao, Maosheng, Li, Lidong, and Guo, Xuefeng

Subjects

*MAGAZINE cover design, *PERIODICAL publishing

Abstract

The front cover design of the international edition of volume 53, number 20, 2014 issue of the journal "Angewandte Chemie" is presented.

Published

2014