The University of Science and Technology is a group of public universities and research institutions in Seoul, Suwon, Changwon, Ansan, Seongnam and Daejeon, in South Korea. The UST was established in 2003 by Korea's government as the nation’s graduate school specializing in science and engineering education and research. The UST runs only a graduate school. It is one of the top science and technology universities in South Korea along with KAIST and POSTECH. Creating the new driving force for growth would play a major role in leading national growth in the 21st century. The South Korean government established the UST to produce professionals in the field of combined technologies, thought of as one of the most important criteria for creating the driving force for South Korea's national growth. Today, UST continues to develop itself into a major research university. Wikipedia.
Shim J.W.,Korean University of Science and Technology
Journal of Computational Physics | Year: 2017
The discretized equilibrium distributions of the lattice Boltzmann method are presented by using the coefficients of the Lagrange interpolating polynomials that pass through the points related to discrete velocities and using moments of the Maxwell–Boltzmann distribution. The ranges of flow velocity and temperature providing positive valued distributions vary with regulating discrete velocities as parameters. New isothermal and thermal compressible models are proposed for flows of the level of the isothermal and thermal compressible Navier–Stokes equations. Thermal compressible shock tube flows are simulated by only five on-lattice discrete velocities. Two-dimensional isothermal and thermal vortices provoked by the Kelvin–Helmholtz instability are simulated by the parametric models. © 2017 Elsevier Inc.
Lee J.,Pohang University of Science and Technology |
Park M.J.,Korean University of Science and Technology
Advanced Energy Materials | Year: 2017
Lawsone (2-hydroxy-1,4-naphthoquinone), a naturally derived red-orange dye, is investigated as a promising cathode material for next-generation lithium batteries. Lithium cells based on lawsone cathode display a high discharge capacity of 280 mA h g-1 (99% theoretical capacity), a high energy density of 664 W h kg-1, and long life of 1000 cycles at 0.5 C along with good rate performance up to 5 C. These results represent significant improvements from previously reported organic cathode materials, and surpass those of conventional lithium batteries based on LiCoO2 cathodes (140 mA h g-1 and 520 W h kg-1, respectively). Its success stems from the unique 2D planar packing of lawsone molecules, with maximized overlap of adjacent p orbitals for redox active sites. The result is the simultaneous enhancement of electrical and ionic conductivities that are an order of magnitude higher than those of other synthetic quinones. Given that lawsone is derived from the henna plant and has long been used as a dye for human hair and skin, this work may open a new chapter in the design of future green batteries. © 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.
Druckmann S.,Howard Hughes Medical Institute |
Feng L.,Korea Institute of Science and Technology |
Lee B.,Korea Institute of Science and Technology |
Lee B.,Korean University of Science and Technology |
And 5 more authors.
Neuron | Year: 2014
The organization of synaptic connectivity within a neuronal circuit is a prime determinant of circuit function. We performed a comprehensive fine-scale circuit mapping of hippocampal regions (CA3-CA1) using the newly developed synapse labeling method, mGRASP. This mapping revealed spatially nonuniform and clustered synaptic connectivity patterns. Furthermore, synaptic clustering was enhanced between groups of neurons that shared a similar developmental/migration time window, suggesting a mechanism for establishing the spatial structure of synaptic connectivity. Such connectivity patterns are thought to effectively engage active dendritic processing and storage mechanisms, thereby potentially enhancing neuronal feature selectivity. © 2014 Elsevier Inc.
El-Gamal M.I.,Korean University of Science and Technology |
Oh C.-H.,Korea Institute of Science and Technology
Current Topics in Medicinal Chemistry | Year: 2010
β-Lactam antibiotics are the most prescribed antibacterial agents. They comprise more than half of all antibiotics. They are considered as the cornerstone of the antibiotic armamentarium. By inhibiting bacterial cell wall biosynthesis, they are highly effective against Gram-positive and Gram-negative bacteria. Antibiotic resistance among Gram-negative pathogens in hospitals represents a dangerous threat to public health. Since many bacteria have developed resistance to older agents, new β-lactam antibiotics have been continuously developed. In the late 1970s, a new class of exceptionally broad-spectrum non-traditional β-lactams, carbapenems, was developed. This review article focuses on the new developments related to the field of carbapenems for treatment of bacterial infections, especially those caused by Gram-negative bacteria. The structural features, principal characteristics, and clinical implications of carbapenems including thienamycin, imipenem/cilastatin, panipenem/betamipron, biapenem, tebipenem, tebipenem pivoxil, meropenem, ertapenem, doripenem, lenapenem, and tomopenem are discussed herein. © 2010 Bentham Science Publishers Ltd.
Lee J.S.,Korea Institute of Science and Technology |
Lee J.S.,Korean University of Science and Technology
Marine Drugs | Year: 2015
The present review summarizes the recent progresses in the synthesis of 2-pyrones and the application to the synthesis of marine natural products. Especially, much attention was placed on the transition metal catalyzed synthetic methodologies in this review. © 2015 by the authors; licensee MDPI, Basel, Switzerland.
Shemorry A.,California Institute of Technology |
Hwang C.-S.,Korean University of Science and Technology |
Varshavsky A.,California Institute of Technology
Molecular Cell | Year: 2013
Nα-terminal acetylation of cellular proteins was recently discovered to create specific degradation signals termed Ac/N-degrons and targeted by the Ac/N-end rule pathway. We show that Hcn1, a subunit of the APC/C ubiquitin ligase, contains an Ac/N-degron that is repressed by Cut9, another APC/C subunit and the ligand of Hcn1. Cog1, a subunit of the Golgi-associated COG complex, is also shown to contain an Ac/N-degron. Cog2 and Cog3, direct ligands of Cog1, can repress this degron. The subunit decoy technique was used to show that the long-lived endogenous Cog1 is destabilized and destroyed via its activated (unshielded) Ac/N-degron if the total level of Cog1 increased in a cell. Hcn1 and Cog1 are the first examples of protein regulation through the physiologically relevant transitions that shield and unshield natural Ac/N-degrons. This mechanistically straightforward circuit can employ the demonstrated conditionality of Ac/N-degrons to regulate subunit stoichiometries and other aspects of protein quality control. © 2013 Elsevier Inc..
Lee W.,Korea Research Institute of Standards and Science |
Lee W.,Korean University of Science and Technology |
Park S.-J.,Korea Research Institute of Standards and Science
Chemical Reviews | Year: 2014
Many desirable engineering properties such as excellent hardness, corrosion, and abrasion resistance can be obtained by anodizing aluminum metals in acid electrolytes. In addition, due to its high porosity, the porous oxide films formed on the metals serve as a good adhesion base for electroplating, painting, and semi-permanent decorative coloration. Porous AAO film grown on aluminum is composed of a thin barrier oxide layer in conformal contact with aluminum, and an overlying, relatively thick, porous oxide film containing mutually parallel nanopores extending from the barrier oxide layer to the film surface. Each cylindrical nanopore and its surrounding oxide region constitute a hexagonal cell aligned normal to the metal surface. Under specific electrochemical conditions, the oxide cells self-organize into hexagonal close-packed arrangement, forming a honeycomb-like structure.
Han H.,Korea Research Institute of Standards and Science |
Huang Z.,Jiangsu University |
Lee W.,Korea Research Institute of Standards and Science |
Lee W.,Korean University of Science and Technology
Nano Today | Year: 2014
Silicon nanostructures exhibit promising application potentials in many fields in comparison with their bulk counterpart or other semiconductor nanostructures. Therefore, the exploiting of controllable fabrication methods of silicon nanostructures, and the exploring of further applications of silicon nanostructures gain extensive attentions. In this review, recent advances in metal-assisted chemical etching of silicon, a low-cost and versatile method enabling fine control over morphology feature of silicon nanostructures, are summarized. The overview concerning the applications of silicon nanostructures in the field of energy conversion and storage, and sensors are also presented. © 2014 The Authors.
Park M.,Korea Institute of Science and Technology |
Park M.,Korean University of Science and Technology |
Shen K.,Stanford University |
Shen K.,Howard Hughes Medical Institute
EMBO Journal | Year: 2012
Wnt proteins play important roles in wiring neural circuits. Wnts regulate many aspects of neural circuit generation through their receptors and distinct signalling pathways. In this review, we discuss recent findings on the functions of Wnts in various aspects of neural circuit formation, including neuronal polarity, axon guidance, synapse formation, and synaptic plasticity in vertebrate and invertebrate nervous systems. © 2012 European Molecular Biology Organization.
Subbiah R.,Korean University of Science and Technology
Journal of the Royal Society, Interface / the Royal Society | Year: 2013
Hybrids consisting of carboxylated, single-walled carbon nanotube (c-SWNT)-silver nanoparticles (AgNPs)-DNA-poly vinyl alcohol (PVA) are synthesized via sequential functionalization to mimic the theragnostic (therapy and diagnosis) system. Carboxylation of SWNT has minimized the metal impurities with plenty of -COOH groups to produce hybrid (c-SWNT-AgNPs). The hybrid is further wrapped with DNA (hybrid-DNA) and encapsulated with PVA as hybrid composite (HC). Materials were tested against human alveolar epithelial cells (A549), mouse fibroblasts cells (NIH3T3) and human bone marrow stromal cells (HS-5). The composition-sensitive physico-chemical interactions, biophysics and biomechanics of materials-treated cells are evaluated. The cell viability was improved for HC, hybrid-PVA and c-SWNT when compared with SWNT and hybrid. SWNT and hybrid showed cell viability less than 60% at high dose (40 μg ml(-1)) and hybrid-PVA and HC retained 80% or more cell viability. The treatment of hybrid nanomaterials considerably changed cell morphology and intercellular interaction with respect to the composition of materials. Peculiarly, PVA-coated hybrid was found to minimize the growth of invadopodia of A549 cells, which is responsible for the proliferation of cancer cells. Surface roughness of cells increased after treatment with hybrid, where cytoplasmic regions specifically showed higher roughness. Nanoindentation results suggest that changes in biomechanics occurred owing to possible internalization of the hybrid. The changes in force spectra of treated cells indicated a possible greater interaction between the cells and hybrid with distinct stiffness and demonstrated the surface adherence and internalization of hybrid on or inside the cells.