Your search keyword '"Huilin Shao"' showing total 4 results

1. Catalytic amplification by transition-state molecular switches for direct and sensitive detection of SARS-CoV-2

Author

Yu Wang, Paul A. Tambyah, Catherine W.M. Ong, Noah R. Sundah, Haitao Zhao, Auginia Natalia, Qing Hao Miow, Nicholas R. Y. Ho, Darius L. L. Beh, Ka Lip Chew, Yuan Chen, Douglas Chan, Huilin Shao, and Yu Liu

Subjects

viruses, Microfluidics, Biophysics, 02 engineering and technology, Molecular nanotechnology, Catalysis, 03 medical and health sciences, Limit of Detection, Lab-On-A-Chip Devices, Humans, skin and connective tissue diseases, Molecular Biology, Research Articles, 030304 developmental biology, Detection limit, Molecular switch, 0303 health sciences, Multidisciplinary, Transition (genetics), SARS-CoV-2, Chemistry, digestive, oral, and skin physiology, fungi, SciAdv r-articles, COVID-19, RNA, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, Fluorescence, body regions, Coronavirus, Point-of-Care Testing, COVID-19 Nucleic Acid Testing, 0210 nano-technology, Research Article

Abstract

Transition-state molecular switches enable hyper responsive detection of SARS-CoV-2 in native clinical samples., Despite the importance of nucleic acid testing in managing the COVID-19 pandemic, current detection approaches remain limited due to their high complexity and extensive processing. Here, we describe a molecular nanotechnology that enables direct and sensitive detection of viral RNA targets in native clinical samples. The technology, termed catalytic amplification by transition-state molecular switch (CATCH), leverages DNA-enzyme hybrid complexes to form a molecular switch. By ratiometric tuning of its constituents, the multicomponent molecular switch is prepared in a hyperresponsive state—the transition state—that can be readily activated upon the binding of sparse RNA targets to turn on substantial enzymatic activity. CATCH thus achieves superior performance (~8 RNA copies/μl), direct fluorescence detection that bypasses all steps of PCR (

Published

2021

2. Exosome-templated nanoplasmonics for multiparametric molecular profiling

Author

Chin-Ann Johnny Ong, Nicholas R. Y. Ho, Xingjie Wu, Huilin Shao, Melissa C. C. Teo, Auginia Natalia, Jimmy Bok Yan So, Haitao Zhao, and Carine Z. J. Lim

Subjects

Physics::Biological Physics, Quantitative Biology::Biomolecules, Multidisciplinary, Chemistry, Quantitative Biology::Molecular Networks, Vesicle, Microfluidics, Biophysics, technology, industry, and agriculture, Physics::Optics, SciAdv r-articles, Optics, Nanotechnology, macromolecular substances, Exosome, Nanoshell, Microvesicles, Gold nanoshells, biological sciences, health occupations, Physics::Atomic and Molecular Clusters, natural sciences, Research Articles, Research Article

Abstract

Biologically templated plasmonics enables simultaneous biophysical and biomolecular analysis of exosome biomarkers., Exosomes are nanoscale vesicles distinguished by characteristic biophysical and biomolecular features; current analytical approaches, however, remain univariate. Here, we develop a dedicated platform for multiparametric exosome analysis—through simultaneous biophysical and biomolecular evaluation of the same vesicles—directly in clinical biofluids. Termed templated plasmonics for exosomes, the technology leverages in situ growth of gold nanoshells on vesicles to achieve multiselectivity. For biophysical selectivity, the nanoshell formation is templated by and tuned to distinguish exosome dimensions. For biomolecular selectivity, the nanoshell plasmonics locally quenches fluorescent probes only if they are target-bound on the same vesicle. The technology thus achieves multiplexed analysis of diverse exosomal biomarkers (e.g., proteins and microRNAs) but remains unresponsive to nonvesicle biomarkers. When implemented on a microfluidic, smartphone-based sensor, the platform is rapid, sensitive, and wash-free. It not only distinguished biomarker organizational states in native clinical samples but also showed that the exosomal subpopulation could more accurately differentiate patient prognosis.

Published

2020

3. Catalytic amplification by transition-state molecular switches for direct and sensitive detection of SARS-CoV-2.

Author

Sundah, Noah R., Natalia, Auginia, Yu Liu, Ho, Nicholas R. Y., Haitao Zhao, Yuan Chen, Qing Hao Miow, Yu Wang, Beh, Darius L. L., Ka Lip Chew, Douglas Chan, Tambyah, Paul A., Ong, Catherine W. M., and Huilin Shao

Subjects

*MOLECULAR switches, *SARS-CoV-2, *EXONUCLEASES, *MERS coronavirus, *COVID-19

Abstract

The article presents a study on a molecular nanotechnology, known as catalytic amplification by transition-state molecular switch (CATCH), which enables direct and sensitive detection of viral RNA targets in severe acute respiratory syndrome coronavirus 2, the casual pathogen of coronavirus disease 2019. It discusses the working principle of the CATCH assay, evaluation of CATCH assay's performance in different cellylar lysates and immobilization of signaling oligonucleotides.

Published

2021

4. Exosome-templated nanoplasmonics for multiparametric molecular profiling.

Author

Xingjie Wu, Haitao Zhao, Natalia, Auginia, Lim, Carine Z. J., Ho, Nicholas R. Y., Ong, Chin-Ann J., Teo, Melissa C. C., So, Jimmy B. Y., and Huilin Shao

Subjects

*EXOSOMES, *FLUORESCENT probes, *APTAMERS, *NANOTECHNOLOGY, *VESICLES (Cytology), *SERS spectroscopy, *LIFE sciences

Abstract

The article discusses exosome-templated nanoplasmonics for multiparametric molecular profiling. It mentions that the nanoshell formation is templated by and tuned to distinguish exosome dimensions for biophysical selectivity. It also mentions that the nanoshell plasmonics locally quenches fluorescent probes only if they are target-bound on the same vesicle for biomolecular selectivity.

Published

2020