A microfluidic device for and methods of using surface-attached posts and capture beads in a microfluidic chamber is disclosed. For example, the microfluidics device includes a pair of substrates separated by a gap and thereby forming a reaction (or assay) chamber therebetween. A field of actuatable surface-attached posts (e.g., magnetically responsive microposts) is provided on one or both of the substrates. The surface-attached posts are functionalized with capture beads. Additionally, methods are provided of functionalizing the surface-attached posts with the capture beads. Additionally, methods are provided of using the surface-attached posts that are functionalized with capture beads in a microfluidics device for binding a target of interest. Further, a bead spraying system and method is provided for spraying magnetically responsive and/or non-magnetically responsive beads atop and/or among a field of surface-attached microposts for use in a microfluidic device.

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.

A method for detecting an analyte reactive towards luminol, comprising the steps of: feeding into a reaction chamber an alkaline solution of luminol, noble metal nanoparticles and at least one analyte reactive towards luminol, wherein the reaction chamber is in the form of a curved channel; detecting the light emitted due to a chemiluminescence reaction taking place in said channel; and discharging a reaction mass from said channel, characterized in that the average diameter of the metal nanoparticles is greater than 25 nm. Also provided is a microfluidic device for carrying out the method.

The present invention relates to provide, among other things, the methods, devices, and systems that can simply and quickly collecting and analyzing a tiny amount of vapor condensates (e.g. exhaled breath condensate (EBC)).

A fluidic device (1) comprises a flow chamber (2) for accommodating a biological specimen on a carrier portion (3) and at least one flow channel (4a, 4b, 4c, 4d) fluidly connected to the flow chamber (2), the fluidic device (1) having a layered structure comprising a bottom plate (5), a cover plate (6) and an insert (7) in between, the insert (7) comprising the carrier portion (3) and a frame portion surrounding the carrier portion (3), and being elastomeric in order to be able to clamp a biological specimen between an incision in the carrier portion (3).

An analysis cartridge includes a first cover, a second cover, a plurality of containers, a plurality of fluid tunnels and a rotary valve. The second cover has two opposite surfaces, a plurality of first through holes and a second through hole individually penetrate through the two opposite surfaces, and the first cover is attached to the second cover. The plurality of containers are disposed between the first cover and the second cover, with each of the containers being aligned to and filled in the first through holes. The plurality of the fluid tunnels are disposed on the first cover, and each of which is individually connected with a first pipette. The rotary valve is rotatably disposed between the first cover and the second cover to correspond to the second through hole, and a flow channel disposed on the rotary valve is connected with the containers individually.

The system includes a pipette tip with a proximal end that has a rim. The rim defines a proximal opening adapted to receive a pipetter, and the rim includes a rim conical edge. The system also has a support card with a top surface, a pipette tip receiver opening within the top surface, the opening adapted to receive the pipette tip and having a receiver opening conical edge. The rim conical edge and the receiver opening conical edge are constructed such that when the pipette tip is disposed of in the pipette tip receiver opening, the rim conical edge abuts the receiver opening conical edge, and the top surface is flush with or nearly flush with the rim.

Device (145) for dispensing drops of liquid, characterised in that it comprises: —at least one container (100) for a liquid, comprising at least one internal chamber and an upper opening, each chamber having a lower aperture and a seal sealing the upper opening, the seal having a substantially planar resiliently deformabie flexible portion, —at least one mechanical actuation means (146) configured to deform a flexible portion of a seal of at least one container, —a means (147) for selecting the volume of a drop to be dispensed from a plurality of drop volumes, a means (148) for determining the volume of liquid present in at least one container, and—a means (149) for controlling the actuation means, which means controls the movement from at least one point of the flexible portion of a container seal, as a non-constant function of the drop volume to be dispensed and the volume of liquid present in the container.

An apparatus for temperature-controlling and thawing a temperature-controlled material which is arranged in at least one rigid container, including an openable housing containing a storage chamber for receiving the at least one container, and including a heating device containing a flat heating element which is operatively connected to the at least one container. A storage mat for receiving the at least one container is arranged between the flat heating element and the at least one container.

A flow stabilized chip includes a chip mainbody, a buffering chamber and two fluid delivery ports. The chip mainbody has a pipe-connection surface. The buffering chamber is disposed in the chip mainbody. The two fluid delivery ports are disposed on the pipe connection surface and connected to the buffering chamber. The chip mainbody includes, in order from the pipe-connection surface to a bottom of the chip mainbody, a first base plate, a first elastic membrane, a second base plate, a second elastic membrane and a third base plate. The first base plate includes a first opening. The second base plate includes a second opening. The third base plate includes a third opening. The first elastic membrane, the second base plate and the second elastic membrane are stacked in sequence to form the buffering chamber.