A cover for a fluid container having an essentially plane cover plate for closing at least one opening of at least one fluid container and at least two ports, and each port has a through channel extending through the entire thickness of the cover plate and a fluid impermeable first membrane is arranged over the entire cross section of the through channel of the first port and an at least gas permeable second membrane is arranged over the entire cross section of the through channel of the second port is disclosed.

Reagent devices including a liquid container and a reagent insert are provided. Aspects of the reagent insert include a first dried reagent composition and a second dried reagent composition distinctly positioned on one or more surfaces of a solid support. Also provided are methods of making and using the reagent device or reagent insert, as well as systems and kits including the same.

A reaction processor includes: a reaction processing vessel including a channel in which a sample moves and a pair of air communication ports, a first air communication port and a second air communication port, provided at respective ends of the channel; a temperature control system that provides a medium temperature region and a high temperature region between the first air communication port and the second air communication port in the channel; and a liquid feeding system that discharges and sucks air in order to move and stop the sample inside the channel. One of the pair of air communication ports of the reaction processing vessel that is farther away from the high temperature region communicates with the liquid feeding system via a tube. One of the pair of air communication ports of the reaction processing vessel that is closer to the high temperature region is opened to atmospheric pressure.

The present invention relates to a biosensor, including: a blood cell separation membrane which separates blood cells from blood and allows plasma components to pass through; a microfluid channel through which the plasma components that have passed through the blood cell separation membrane flow; a lower substrate which allows the plasma components that have passed through the blood cell separation membrane to flow along the microfluid channel; and a pillar which connects the blood cell separation membrane and the lower substrate, in which an electrode is disposed in the pillar, and the pillar pushes and lifts the blood cell separation membrane by a predetermined distance. The biosensor of the present invention allows plasma, which is difficult to pass through the blood cell separation membrane due to surface tension, to easily pass through.

A device for isolating a biological material from a sample includes a housing, a slider and a dry reagent capsule. The housing defines a plurality of compartments and a plurality of fluid channels. Each compartment is configured to be fluidically connected to a respective fluid channel, and each fluid channel includes a respective end terminating at a track disposed on the housing. The slider is movable along the track and includes a plurality of connecting channels extending therethrough. A selected one of the connecting channels is configured to connect ends of selected ones of the fluid channels based on a position of the slider along the track. The dry reagent capsule is configured to be mounted to the housing, and includes at least one dry reagent for mixing with the sample. The dry reagent capsule is further configured to be fluidically connected to a respective fluid channel in-situ.

Devices for detecting microorganism strains or target cellular analytes are provided. The device includes a filter holder, the filter holder comprising a tip portion; a nonwoven article disposed on the tip portion of the filter holder; and an adaptor attacked to the filter holder, the adaptor defining an aperture. Methods of detecting microorganisms and/or cellular analytes in a fluid sample using the devices are also provided. The method includes obtaining the device; placing a lumened or cannulated device in fluid communication with the device; and passing a fluid sample suspected of containing at least one microorganism strain or target cellular analyte from the lumened or cannulated device through the device and contacting the nonwoven article. The method further includes contacting the nonwoven article with at least one detection reagent and detecting the presence of the at least one microorganism strain or target cellular analyte concentrated by the nonwoven article. Kits and systems including the devices are also provided.

Provided is a channel device that is capable of increasing the concentration of fine particles in a liquid only by use of fluid-dynamic flows without relying on electrostatic interactions. A channel device (1) in accordance with an embodiment of the present invention includes: a main channel (11) configured to allow a liquid containing fine particles to flow therethrough; a chamber (15) that is provided at an end of the main channel (11) and that is configured to store target fine particles which have increased in concentration; and a side channel (12) that is connected to a side face of the main channel (11) and that is configured to allow unwanted liquid to drain therethrough, wherein at least one of a height and a width of the side channel (12) is smaller than a particle size of the fine particles.

Cell separation systems, and methods for separating cells from microcarriers, and harvesting the separated cells, are provided, wherein the system comprises a cell separation device, a cell settling device, and a cell screening device.

The invention provides a microfluidic system comprising a cartridge coupled to a motor and adapted to move a fluid sample to a plurality of locations on the cartridge.

A device for blood (1) is provided with a column (50) and a micro flow path (20) located downstream of the column (50). The column (50) includes a porous material as a solid phase, and blood that has contacted with the porous material flows through the micro flow path (20). In the device for blood (1), the column (50) and the micro flow path (20) are provided as separated bodies. The column (50) has a connecting part (55), the micro flow path (20) has an inlet (21a), the connecting part (55) and the inlet (21a) are connected to each other to integrate the column (50) with the micro flow path (20), and blood (BL) is allowed to pass from the column (50).