Abstract: A nanogap device includes a first insulation layer having a nanopore formed therein, a first nanogap electrode which may be formed on the first insulation layer and may be divided into two parts with a nanogap interposed between the two parts, the nanogap facing the nanopore, a second insulation layer formed on the first nanogap electrode, a first graphene layer formed on the second insulation layer, a first semiconductor layer formed on the first graphene layer, a first drain electrode formed on the first semiconductor layer, and a first source electrode formed on the first graphene layer such as to be apart from the first semiconductor layer.

Abstract: A nanogap device which may include a first insulation layer having a nanopore formed therein, a first channel layer which may be on the first insulation layer, a first source electrode and a first drain electrode which may be respectively in contact with both ends of the first channel layer, a second insulation layer which may cover the first channel layer, the first source electrode, and the first drain electrode, and a first nanogap electrode which may be on the second insulation layer and may be divided into two parts with a nanogap, which faces the nanopore, interposed between the two parts.

Abstract: Provided is a device with a nanopore that has a thiol-containing material bound to a gold layer, methods of producing the devices, and methods of analyzing nucleic acid using the devices.

Abstract: A method and a device for detecting nucleic acid are disclosed, wherein impurities in a sample can be easily removed. The method comprises injecting a sample containing an adsorption medium with nucleic adsorbed thereon into a chamber; washing the sample; heating the sample to denature the nucleic acid; cooling down; and detecting nucleic acid by using the biomolecule detection device. The device includes: a source and a drain region; a gate electrode layer; a chamber formed over the semiconductor substrate including the gate electrode layer; and a heating means, wherein a gate adsorption layer to which a nucleic acid is adsorbed is formed on the gate electrode layer. A single-stranded nucleic acid is adsorbed to the gate adsorption layer, and a channel is formed between the source and the drain region. The current in the channel provides a basis to detect a gene.

Abstract: A method of determining or estimating a nucleotide sequence of a nucleic acid by using a device with a nanopore.

Abstract: Provided is a device for determining a monomer molecule sequence of a polymer including different electrodes, and a method of efficiently determining a monomer molecule sequence of a polymer.

Abstract: A nanogap sensor includes a first layer in which a micropore is formed; a graphene sheet disposed on the first layer and including a nanoelectrode region in which a nanogap is formed, the nanogap aligned with the micropore; a first electrode formed on the grapheme sheet; and a second electrode formed on the graphene sheet, wherein the first electrode and the second electrode are connected to respective ends of the nanoelectrode region.

Abstract: A biomolecule detection apparatus comprising a nanopore device having a front surface and rear surface and including a nanopore having a nano-sized diameter; a reservoir disposed adjacent to a rear surface of the nanopore device; and a power supply unit comprising a first electrode disposed in a front of the nanopore device; a second electrode disposed inside the reservoir; and a third electrode disposed adjacent the nanopore and between the first electrode and the second electrode; as well as a method of using the biomolecule detection apparatus to detect a biomolecule in a sample.

Abstract: A nanopore device including a nanopore formed by penetrating a thin layer, a nanochannel formed at an entrance of the nanopore, and a filler in the nanochannel, as well as a method of fabricating the nanopore device and an apparatus including the nanopore device.

Abstract: An apparatus and method for linearly translocating nucleic acid molecules through an aperture at a reduced rate.

Abstract: Provided are a FET-based sensor for detecting an ionic material, an ionic material detecting device including the FET-based sensor, and a method of detecting an ionic material using the FET-based sensor. The FET-based sensor includes: a sensing chamber including a reference electrode and a plurality of sensing FETs; and a reference chamber including a reference electrode and a plurality of reference FETs. The method includes: flowing a first solution into and out of the sensing chamber and the reference chamber of the FET-based sensor; flowing a second solution expected to contain an ionic material into and out of the sensing chamber while continuously flowing the first solution into and out of the reference chamber; measuring a current in a channel region between the source and drain of each of the sensing and reference FETs; and correcting the current of the sensing FETs.

Abstract: A nanosensor comprising a substrate having a hole; a first insulating layer disposed on the substrate and having a first nanopore at a location corresponding to the hole in the substrate; first and second electrodes disposed on the first insulating layer, wherein the first and second electrodes are spaced apart from each other with the first nanopore positioned therebetween; a first electrode pad disposed on at least a portion of the first electrode; a second electrode pad disposed on at least a portion of the second electrode; and a protective layer disposed on at least a portion of the first and second electrode pads; as well as a method for manufacturing same.

Abstract: The present disclosure includes a sensor and method for detecting a target molecule. In one instance, a sensor comprises a substrate including a hole, a first insulating layer located on the substrate and including a first nanopore corresponding to the hole, a first electrode, a second electrode, wherein the first electrode and the second electrode are located on a surface of the first insulating layer and are spaced apart by the first nanopore forming a nanogap, and a modulation unit configured to apply a unit input signal between the first electrode and the second electrode, wherein at least one unit input signal is applied as a target molecule passes through the nanogap.

Abstract: A field effect transistor for detecting an analyte having a thiol group includes a substrate, a source region and a drain region formed apart from each other on the substrate, the source region and the drain region being doped such that a polarity of the source and drain region is opposite to a polarity of the substrate, a channel region disposed between the source region and the drain region, an insulating layer formed of an electrically insulating material and disposed on the channel region, a gold layer disposed on the insulating layer and a reference electrode disposed apart from the gold layer.

Abstract: Provided is a method of preparing a patterned spot microarray using a photocatalyst. The method comprises coating the photocatalyst on a substrate to form a photocatalyst layer, coating a composition comprising a functional group to be connected to a biomolecule on the photocatalyst layer to form an organic layer, spotting the biomolecule on the organic layer, positioning a photomask above a spot of the biomolecule; and irradiating the spot through the photomask to pattern the spot.

Abstract: A nanosensor comprising a substrate in which an opening defining a hole is formed; a first layer disposed on the substrate, which comprises a first nanopore in communication with the hole in the substrate; and a second layer contacted or coupled with the first layer and formed of a porous material.

Abstract: A device for detecting biomolecules includes: a semiconductor substrate; a source region and a drain region separately provided at the substrate; a chamber formed at the substrate including a region between the source region and the drain region, the chamber configured to contain a sample including the biomolecules; and an electrode which applies a voltage to the sample in the chamber. The biomolecules are mobile with respect to the electrode and sample. Methods for detecting biomolecules are also disclosed.

Abstract: A kit and method for predicting the sensitivity of gastric cancer patient to an anti-cancer agent are disclosed.

Abstract: A device for calibrating an optical scanner includes a substrate; and a pattern disposed on the substrate, the pattern comprising a photoresist.

Abstract: A method of detecting a presence of bio-molecules, or a concentration of the target bio-molecules using a field effect transistor, includes allowing a first sample including a first target bio-molecule to contact a sensing surface of the field effect transistor and measuring a change in an electric signal of the field effect transistor, the field effect transistor including a substrate, a source region and a drain region, the source region and the drain region formed apart from each other on the substrate, the source region and the drain region each doped to having an opposite polarity than a polarity of the substrate, a channel region disposed between the source region and the drain region and an insulating layer including the sensing surface, the insulating layer disposed on the channel region.