Abstract: Provided are a microfluidic device including an electrolysis device for cell lysis which includes an anode chamber, a cathode chamber and a separator, in which the separator is installed between the anode chamber and the cathode chamber, the anode chamber includes an inlet and an outlet for an anode chamber solution and an electrode, and the cathode chamber includes an inlet and an outlet for a cathode chamber solution and an electrode, and a method of electrochemically lysing cells using the same.

Abstract: Provided is a method of isolating and purifying nucleic acids using an immobilized hydrogel or polyethylene glycol (PEG)-hydrogel copolymer. The method includes: immobilizing a functional group-containing hydrogel or PEG-hydrogel copolymer on a substrate; adding a mixed sample solution containing a salt and nucleic acids to the hydrogel- or PEG-hydrogel copolymer-immobilized substrate to bind the nucleic acids to the hydrogel or the PEG-hydrogel copolymer; washing the nucleic acid-bound hydrogel or PEG-hydrogel copolymer; and eluting the nucleic acids from the hydrogel or the PEG-hydrogel copolymer using an elution solvent. Therefore, binding and elution of nucleic acids can be performed even with no addition of a separate chemical substance, and an effect on a subsequent process such as PCR can be minimized. Furthermore, the amount and intensity for binding nucleic acids can be adjusted according to PEG concentration, and the presence of a hydrogel compound on a substrate enables patterning.

Abstract: Provided is a lysis method for cells or viruses, including: immobilizing a metal-ligand complex on a solid support; and mixing the complex immobilized on the support with a cell or virus solution. According to the lysis method, by immobilizing a chemical on a solid support to perform cell lysis, the dilution problem according to the addition of a cell lysis solution can be resolved and a separate process of removing the chemical is not required so as to reduce the steps upon LOC implementation. In addition, since a variety of solid supports, such as chips, beads, nanoparticles etc. can be used, cell lysis apparatuses of various forms can be fabricated.

Abstract: Provided is a method of storing a substrate having an active group or a probe molecule immobilized thereon. The method includes attaching a UV film to a surface of the substrate having the active group or probe immobilized thereon; and exposing the UV film to UV light, wherein the UV film comprises a UV-permeable base film and a pressure sensitive adhesive layer formed on a surface of the UV-permeable base film to immobilize the substrate, and when the pressure sensitive adhesive layer is exposed to the UV light, its adhesive force decreases.

Abstract: A microarray substrate having a patterned thin layer on a substrate is provided. In the microarray substrate, the substrate has a reflectance different from that of a material of the thin layer, and the patterned thin layer includes a spot region having a thickness at which constructive interference occurs between a first reflected light of irradiated excitation light reflected from the substrate and a second reflected light of irradiated excitation light reflected from the thin layer and a background region having a thickness at which destructive interference occurs between the first reflected light of irradiated excitation light reflected from the substrate and the second reflected light of irradiated excitation light reflected from the thin layer.

Abstract: Provided are a method of producing a substrate having a patterned organosilane layer and a method of using the substrate having the patterned organosilane layer. The method of producing the substrate having the patterned organosilane layer, includes: coating organosilane on a substrate to obtain an organosilane layer; coating a photoresist material on the organosilane layer; exposing the photoresist material to light through a mask to obtain a patterned surface on the photoresist material; developing an exposed or unexposed region of the photoresist material using a developer; and wet etching a portion of the organosilane layer in the region from which the photoresist material has been removed, using a HF-containing solution as an etchant.

Abstract: Provided is a method for immobilizing a biomolecule on a solid substrate. The method includes coating the solid substrate with silane anhydride to introduce an anhydride functional group onto a surface of the solid substrate; obtaining a carboxyl group from the anhydride functional group by hydrolysis; reacting the carboxyl group with carbodiimide and succinimide to activate the carboxyl group; and contacting the biomolecule with the solid substrate having the activated carboxyl group on its surface to immobilize the biomolecule on the solid substrate.