The objective of the present invention is to provide a particle detection device and a particle detection method that can individually and continuously detect a wide range of particles. The objective is achieved by a particle detection device including: a particle separation channel through which particles are separated according to particle sizes in a perpendicular direction to the flow of fluid; and two or more particle recovery channels that are connected to and branched from the particle separation channel, in which each of the particle recovery channels includes a particle detection unit that includes an aperture and an electric detector.

A micro-nano particle detection device and method are disclosed. The device includes a sample chamber and at least two measurement chambers, where at least one through hole is formed between each measurement chamber and the sample chamber, each measurement chamber is communicated with the sample chamber only through the through hole, a common electrode is arranged in the sample chamber, a measurement electrode is arranged in each measurement chamber respectively, a first end of the sample chamber is provided with a first liquid driving device, and the common electrode is grounded.

Disclosed is a device for analyzing a single cell using a micropore including an inlet chamber; an outlet chamber provided on an opposite side of the inlet chamber; a pore membrane disposed between the inlet chamber and the outlet chamber; a pressure generating means provided in the inlet chamber or the outlet chamber; and a pair of electrodes respectively disposed in front and rear of the pore membrane, wherein a diameter D of the micropore is larger than a diameter of the target cell, a thickness t of the pore membrane is 0.5 μm to 1 mm, and a slenderness ratio (t/D) is 0.001 to 5.

An apparatus comprising: a body having an aperture dimensioned to receive an air-borne particle of corresponding size; first and second electrodes positioned within the aperture between which a potential difference can be applied; and a measurement circuit configured to measure an electrical property between the first and second electrodes such that the presence of the air-borne particle within the aperture can be detected based on a change in the electrical property when the air-borne particle contacts both the first and second electrodes.

According to one embodiment, provided is a single particle analyzing device including a measuring vessel, first and second chambers in the vessel defined by an insulating membrane, a pore opening in the membrane to connect the chambers, and first and second electrodes in the chambers. Electric current flows between the electrodes through the pore. Electrical characteristics are measured during migration of the target from the first chamber to the second chamber to measure the size and shape of the target. (a) t<a <d≦100a or (b) s<L, s<d≦100s, t<L and t<d, wherein a, L and s are the diameter, length and width of the target, d is the diameter of the pore, and t is the thickness of the membrane in the proximity to the pore.

Provided are a device and a method for rapidly and simply detecting endotoxin without using an expensive reagent. The endotoxin detection device includes: a region containing an electrolyte solution; a partitioning member that partitions the region into two compartments such that the two compartments are in communication via a nanopore; a first electrode that is disposed in a first compartment; a second electrode that is disposed in a second compartment and is electrically connected to the first electrode; an electrolyte solution flow generating means that causes electrolyte solution in the first compartment to move to the second compartment via the nanopore; an application means that applies voltage between the first electrode and the second electrode; and a monitoring means that monitors current.

Systems and methods to integrate electrical sensors comprising parallel electrodes into microfluidic devices that are manufactured using soft lithography are disclosed herein. With minimal fabrication complexity, more uniform electric fields than conventional coplanar electrodes are produced. The methods disclosed are also more suitable for the construction of complex electrical sensor networks in microfluidic devices due to greater layout flexibility and provide improved sensitivity over conventional coplanar electrodes.

A method of forming a nanopore in a lipid bilayer is disclosed. A nanopore forming solution is deposited over a lipid bilayer. The nanopore forming solution has a concentration level and a corresponding activity level of pore molecules such that nanopores are substantially not formed un-stimulated in the lipid bilayer. Formation of a nanopore in the lipid bilayer is initiated by applying an agitation stimulus level to the lipid bilayer. In some embodiments, the concentration level and the corresponding activity level of pore molecules are at levels such that less than 30 percent of a plurality of available lipid bilayers have nanopores formed un-stimulated therein.

A method of forming a nanopore in a lipid bilayer is disclosed. A nanopore forming solution is deposited over a lipid bilayer. The nanopore forming solution has a concentration level and a corresponding activity level of pore molecules such that nanopores are substantially not formed un-stimulated in the lipid bilayer. Formation of a nanopore in the lipid bilayer is initiated by applying an agitation stimulus level to the lipid bilayer. In some embodiments, the concentration level and the corresponding activity level of pore molecules are at levels such that less than 30 percent of a plurality of available lipid bilayers have nanopores formed un-stimulated therein.

The present invention relates to a biomolecule detection apparatus capable of easily and quickly detecting various biomolecules associated with diseases and determining the presence or absence of a specific disease. The biomolecule detection apparatus of the present invention includes a micropore device, a microchip, and sensing electrodes. According to the present invention, a microscale pore is formed inside the micropore device. In addition, the microchip is configured to pass through the microscale pore along the flow of a conductive liquid supplied inside the micropore device, has a surface coated with a sensing molecule complementarily bound to a target biomolecule, and has a unique code for identifying the complementarily bound target biomolecule. The sensing electrodes serve to sense the code by measuring change in current flowing through the pore when the microchip passes through the pore.