Your search keyword '"Sung Min Kang"' showing total 3 results

1. Norepinephrine: material-independent, multifunctional surface modification reagent

Author

Sung Min Kang, Junsung Rho, Choi, Insung S., Messersmith, Phillip B., and Haeshin Lee

Subjects

Noradrenaline -- Chemical properties, Oxidation-reduction reaction -- Analysis, Polymerization -- Analysis, Precious metals -- Chemical properties, Chemistry

Abstract

A facile approach is examined for material-independent surface modification by using norepinephrine. pH-Induced oxidative polymerization of norepinephrine has formed adherent films on different types of material surfaces of noble metals, metal oxides, semiconductors, ceramics, shape-memory alloys and synthetic polymers and secondary

Published

2009

2. Mussel-inspired encapsulation and functionalization of individual yeast cells

Author

Haeshin Lee, Sung Min Kang, Sung Ho Yang, Kyung-Bok Lee, Insung S. Choi, and Taek Dong Chung

Subjects

Streptavidin, Chemistry, Dopamine, Nanotechnology, Biocompatible Materials, General Chemistry, Mussel inspired, Saccharomyces cerevisiae, Cells, Immobilized, Biochemistry, Catalysis, Yeast, Bivalvia, chemistry.chemical_compound, Colloid and Surface Chemistry, Biomimetics, Surface modification, Animals

Abstract

The individual encapsulation of living cells has a great impact on the area of cell-based sensors and devices as well as fundamental studies in cell biology. In this work, living yeast cells were individually encapsulated with functionalizable, artificial polydopamine shells, inspired by an adhesive protein in mussels. Yeast cells maintained their viability within polydopamine, and the cell cycle was controlled by the thickness of the shells. In addition, the artificial shells aided the cell in offering much stronger resistance against foreign aggression, such as lyticase. After formation of the polydopamine shells, the shells were functionalized with streptavidin by utilizing the chemical reactivity of polydopamine, and the functionalized cells were biospecifically immobilized onto the defined surfaces. Our work suggests a biomimetic approach to the encapsulation and functionalization of individual living cells with covalently bonded, artificial shells.

Published

2011

3. Mussel-Inspired Encapsulation and Functionalization of Individual Yeast Cells.

Author

Sung Ho Yang, Sung Min Kang, Kyung-Bok Lee, Taek Dong Chung, Haeshin Lee, and Choi, Insung S.

Subjects

*YEAST, *MUSSELS, *CELLS, *SEASHELLS, *STREPTAVIDIN, *CELL cycle, *BIOLOGICAL rhythms

Abstract

The individual encapsulation of living cells has a great impact on the area of cell-based sensors and devices as well as fundamental studies in cell biology. In this work, living yeast cells were individually encapsulated with functionalizable, artificial polydopamine shells, inspired by an adhesive protein in mussels. Yeast cells maintained their viability within polydopamine, and the cell cycle was controlled by the thickness of the shells. In addition, the artificial shells aided the cell in offering much stronger resistance against foreign aggression, such as lyticase. After formation of the polydopamine shells, the shells were functionalized with streptavidin by utilizing the chemical reactivity of polydopamine, and the fun ctionalized cells were biospecifically immobilized onto the defined surfaces. Our work suggests a biomimetic approach to the encapsulation and functionalization of individual living cells with covalently bonded, artificial shells. [ABSTRACT FROM AUTHOR]

Published

2011