Abstract: A method of positively detecting toxic materials within a sample, the method including contacting sub-mitochondrial particles having competent mitochondrial enzymes formed from inner membranes of mitochondria, an electron donor which transmits electrons to an electron transfer system of the sub-mitochondrial particles and the sample, and forming reaction resultants, adjusting a pH of a pH indicator which change color according to a change in pH, adding the pH indicators to each reaction resultant and identifying color changes of the pH indicator. Also provided is a kit for positively detecting toxic materials within a sample.

Abstract: Provided is a sensor for detecting a biomolecule, which includes: a substrate; a first material, immobilized on the substrate, having a cavity structure; a secondary material capable of selectively binding to the cavity structure of the first material and having electrochemical activity; and a probe biomolecule immobilized to the secondary material. A method of manufacturing the biomolecule detection sensor and a method of detecting a biomolecule using the biomolecule detection sensor are also provided. Therefore, a target biomolecule can be easily detected using an electrochemical reaction with high accuracy within a short time. Furthermore, there is no need to elaborately design probes, and thus, the biomolecule detection sensor can be easily manufactured. In addition, label-free detection is possible, which simplifies a detection process, and there is no need to use expensive auxiliary equipment.

Abstract: Provided is a method of manufacturing a microfludic device in which coating film patterns made of a coupling agent are formed in microchannels. The method includes: forming the coating film patterns made of the coupling agent on a Si substrate; selectively oxidizing coupling agent-free regions of the Si substrate having thereon the coating film patterns made of the coupling agent using an oxidizing agent with an oxidation potential from 1 to 2 V; and adhering a PDMS (polydimethylsiloxane) microchannel structure to the selectively oxidized Si substrate to form the microchannels.

Abstract: Provided is a method of sensing biomolecules using a bioFET, the method including: forming a layer including Au on a gate of the bioFET; forming a probe immobilized on a substrate separated from the gate by a predetermined distance, and a biomolecule having a thiol group (—SH) which is incompletely bonded to the probe; reacting the probe with a sample including a target molecule; and measuring a current flowing in a channel region between a source and a drain of the bioFET.

Abstract: Provided is a field effect transistor (FET) type biosensor including a source electrode, a gate, and a drain electrode. A ligand that can bind to a side of a nucleic acid is added to the surface of the gate. In a conventional FET type biosensor, it is difficult to detect a signal within the debye length because a target nucleic acid is directly fixed to the surface of a gate of the conventional FET. However, in the present invention, this problem can be overcome and the debye length can be increased by treating the surface of a gate of an FET sensor with a ligand that can bind to a side of a nucleic acid. The ligand can be adsorbed onto the surface of the gate. In this case, the nucleic acid is adsorbed parallel to the surface of the gate, not perpendicular to the surface of the gate, thus generating an effective depletion region. In addition, hybridization efficiency can be increased because a hybridized sample can be injected into an FET sensor at high ionic strength.

Abstract: A packing device used to pack a sample inlet formed in an upper cover of a chamber is provided. The packing device has an air vent formed in the surface of an upper portion of the sample inlet contacting a cap or in the surface of a lower portion of the cap contacting the sample inlet. The movement of the sample solution in the chamber can be prevented by using a structural design in which air pressure generated due to the volume of a packing cap inserted into the sample inlet after the sample is injected into the chamber through the sample inlet to react with reaction materials, such as biomolecules, is not generated inside of the chamber. In addition, in a hybridization chamber in which a biochip is placed, the spot area on the biochip can be effectively agitated with the sample solution, thus increasing hybridization efficiency.

Abstract: Provided is a calibration apparatus for an optical scanner, including a substrate on which a molecule capable of forming an excimer is immobilized. A method of manufacturing the calibration apparatus and a method of calibrating an optical scanner using the calibration apparatus are also provided.

Abstract: Provided are a sensing switch and a sensing method using the same. The sensing switch includes: a substrate; a supporter on the substrate; a sensing plate that is connected to a side of the supporter and is in parallel with the substrate by a predetermined distance; a receptor binding region on an upper surface of an end portion of the sensing plate; an electric or magnetic field generation device that induces deflection of the sensing plate when a receptor bound to the receptor binding region is selectively bound to an electrically or magnetically active ligand; and a pair of switching electrodes that are separated by a predetermined distance and is connected when the sensing plate contacts the substrate due to the deflection of the sensing plate. A target material need not be labelled, a signal processing of a fluorescent or electrical detection signal using an analysis apparatus is not required, and a signal can be directly decoded by confirming whether a current flows through the switch.

Abstract: Provided are nucleic acid isolation unit and method. The method includes immobilizing an aromatic compound-containing nucleic acid intercalator on a solid support; contacting a first buffer solution containing a nucleic acid sample to be purified to the intercalator immobilized on the solid support to bind the intercalator with nucleic acids contained in the nucleic acid sample; cleaning the resultant structure where the nucleic acids are bound to the intercalator immobilized on the solid support; and eluting the nucleic acids with a second buffer solution.

Abstract: Provided is a hybridization system for hybridizing a biochip including: a chamber device including at least a hybridization chamber including a support for a biochip and a first cover having a sample inlet; an agitation device including: two air channels connected to ends of the hybridization chamber; two valves disposed in the air channels; an integrated air channel to which the two air channels are connected; and an air pump disposed in the integrated air channel; and a washing and drying device including: a flow channel connected to one of the two air channels through a branched valve; a flow pump disposed in the flow channel; and a buffer inlet disposed opposite the flow channel.

Abstract: Provided is an agitation device used to agitate a solution in a hybridization chamber, the agitation device including: the hybridization chamber; first and second air channels connected to ends of the hybridization chamber; a first valve disposed in the first air channel; a second valve disposed in the second air channel; an integrated air channel connecting the first and second air channels; and a pump disposed in the integrated air channel. The agitation device is suitable for effective diffusion of a sample when performing hybridization using a DNA chip. Therefore, a probe can be effectively hybridized with a target material.

Abstract: A method for forming a pattern of carbon nanotubes includes forming a pattern on a surface-treated substrate using a photolithographic process, and laminating carbon nanotubes thereon using a chemical self-assembly process so as to form the carbon nanotubes in a monolayer or multilayer structure. A monolayer or multilayer carbon nanotube pattern may be easily formed on the substrate, e.g., glass, a silicon wafer and a plastic. Accordingly, the method can be applied to form patterned carbon nanotube layers having a high conductivity, and thus will be usefully utilized in the manufacturing processes of energy storages, for example, solar cells and batteries, flat panel displays, transistors, chemical and biological sensors, semiconductor devices and the like.

Abstract: A composition containing a photoacid generator monomer and surfactant, and a method for synthesizing a compound on a substrate using the composition are provided. The method includes bonding a layer of first molecules having an acid labile protecting group to a solid substrate; coating a layer of the photoacid generator monomer composition according to the present invention on the layer of first molecules; exposing the composition layer to light and then heat-treating to remove the acid labile protecting group from the first molecules corresponding to the exposed portion; washing and removing the composition layer from the exposed and unexposed portions; and bonding second molecules to the exposed first molecules.

Abstract: A method for forming a pattern of carbon nanotubes includes forming a pattern on a surface-treated substrate using a photolithographic process, and laminating carbon nanotubes thereon using a chemical self-assembly process so as to form the carbon nanotubes in a monolayer or multilayer structure. A monolayer or multilayer carbon nanotube pattern may be easily formed on the substrate, e.g., glass, a silicon wafer and a plastic. Accordingly, the method can be applied to form patterned carbon nanotube layers having a high conductivity, and thus will be usefully utilized in the manufacturing processes of energy storages, for example, solar cells and batteries, flat panel displays, transistors, chemical and biological sensors, semiconductor devices and the like.