Abstract: The present invention relates to a colorimetric biosensor, preparation method thereof, and antibiotic susceptibility testing method using the same, and more specifically, in the present invention, it is possible to prepare a colorimetric biosensor comprising a porous hydrogel structure including polydiacetylene and a hydrogel polymer (alginate, PEG-DA, etc.); and a microbial nutrient source, and it may be applied to a colorimetric biosensor for detecting microorganisms or a method for testing antibiotic susceptibility of microorganisms for allowing in real-time measurement and exhibiting excellent sensitivity using the colorimetric biosensor.

Abstract: An energy harvesting system based on reverse electro wetting on a dielectric includes: a dielectric material layer molded with a dielectric material in a panel shape and including an upper end and a lower end; and an electrode layer including a plurality of electrodes coupled to a lower surface of the dielectric material layer. In particular, the upper end of the dielectric material layer is located higher than the lower end and allows a liquid drop to flow from the upper end to the lower end, and the dielectric material layer generates dielectric polarization in the dielectric material layer and continuously varies a flow rate of the liquid drop between the upper end and the lower end of the dielectric material layer. The plurality of electrodes are disposed to be spaced apart from one another in a direction from the upper end to the lower end.

Abstract: A hybrid type filtration structure for filtering liquid includes a first active layer, a porous supporting layer and a permeable layer. The first active layer has a first nano pore inner wall of which a function group included compound is combined with. The porous supporting layer has a plurality of pores and is disposed under the first active layer. The permeable layer is disposed under the porous supporting layer. The porous supporting layer includes a plurality of lipid bilayers having membrane protein inside of the pore, a molecule of water selectively passes through the membrane protein. The first nano pore passes through the first active layer vertically. The first nano pore and the pore are connected with each other through which liquid flows.

Abstract: An energy harvesting system based on reverse electro wetting on a dielectric includes: a dielectric material layer molded with a dielectric material in a panel shape and including an upper end and a lower end; and an electrode layer including a plurality of electrodes coupled to a lower surface of the dielectric material layer. In particular, the upper end of the dielectric material layer is located higher than the lower end and allows a liquid drop to flow from the upper end to the lower end, and the dielectric material layer generates dielectric polarization in the dielectric material layer and continuously varies a flow rate of the liquid drop between the upper end and the lower end of the dielectric material layer. The plurality of electrodes are disposed to be spaced apart from one another in a direction from the upper end to the lower end.

Abstract: The present disclosure relates to a liquid filtration structure with one or more macromolecule membrane structures including membrane proteins selectively permeable to water molecules and fixed within a pore. A liquid filtration structure according to an exemplary embodiment of the present disclosure increases stability and durability of macromolecule membrane structures including membrane proteins selectively permeable to water molecules, and, thus, can be effectively used in a filtration device for purifying water.

Abstract: A hybrid type filtration structure for filtering liquid includes a first active layer, a porous supporting layer and a permeable layer. The first active layer has a first nano pore inner wall of which a function group included compound is combined with. The porous supporting layer has a plurality of pores and is disposed under the first active layer. The permeable layer is disposed under the porous supporting layer. The porous supporting layer includes a plurality of lipid bilayers having membrane protein inside of the pore, a molecule of water selectively passes through the membrane protein. The first nano pore passes through the first active layer vertically. The first nano pore and the pore are connected with each other through which liquid flows.

Abstract: The present disclosure relates to a liquid filtration structure with one or more macromolecule membrane structures including membrane proteins selectively permeable to water molecules and fixed within a pore. A liquid filtration structure according to an exemplary embodiment of the present disclosure increases stability and durability of macromolecule membrane structures including membrane proteins selectively permeable to water molecules, and, thus, can be effectively used in a filtration device for purifying water.

Abstract: A liquid filtering structure having high filtering efficiency, excellent transparency, and excellent durability can be provided. The liquid filtering structure includes a filtering layer, wherein the filtering layer includes a nanopore structure unit including a plurality of nanopores and a functional group-containing compound including functional groups at one end, and has selectivity with respect to liquid molecules to be filtered, for example, water molecules, and effectively filter liquid, particularly water by preventing ions or compounds from being passed.

Abstract: Disclosed herein are compositions, methods, and devices related to bilayer and monolayer membranes, their encapsulation in a hydrogel, and their formation. Methods of using the disclosed compositions and devices are also disclosed.

Abstract: Disclosed are membrane precursors and membranes formed therefrom. Also disclosed are methods of making biomimetic membrane precursors and membranes formed therefrom. Methods of using, including methods of storing and handling biomimetic membrane precursors and membranes formed therefrom, are also disclosed.

Abstract: Disclosed are biomimetic membrane precursors and membranes formed therefrom. Also disclosed are methods of making biomimetic membrane precursors and membranes formed therefrom. Methods of using, including methods of storing and handling biomimetic membrane precursors and membranes formed therefrom, are also disclosed.

Abstract: Disclosed herein are compositions, methods, and devices related to bilayer and monolayer membranes, their encapsulation in a hydrogel, and their formation. Methods of using the disclosed compositions and devices are also disclosed.

Abstract: Disclosed herein are compositions, methods, and devices related to bilayer and monolayer membranes, their encapsulation in a hydrogel, and their formation. Methods of using the disclose compositions and devices are also disclosed.

Abstract: Disclosed are biomimetic membrane precursors and membranes formed therefrom. Also disclosed are methods of making biomimetic membrane precursors and membranes formed therefrom.

Abstract: Disclosed herein are compositions, methods, and devices related to bilayer and monolayer membranes, their encapsulation in a hydrogel, and their formation. Methods of using the disclose compositions and devices are also disclosed.