An apparatus includes a fluid reservoir and a laminate fluidic circuit positioned above the fluid reservoir. The laminate fluidic circuit includes two or more layers laminated together to define a substantially planar substrate and one or more channels defined within the substrate. The laminate fluidic circuit includes a flexible conduit defined by a portion of the substrate encompassing an extent of at least one of the channels that is partially separated or separable from the remainder of the substrate. The flexible conduit is deflectable with respect to the planar substrate toward the fluid reservoir such that the flexible conduit fluidly connects the at least one channel to the fluid reservoir.

A liquid handling device includes a common channel, a plurality of wells, a magnetic beads chamber and a plurality of valves. The plurality of valves are rotary membrane valves disposed on the circumference of a first circle. The magnetic beads chamber is disposed on a circumference of the second circle concentric with the first circle.

A system includes a fluidic device, a flow control valve, a first reagent fluid reservoir fluidly connectable to the fluidic device by the flow control valve, a first fluid buffer reservoir fluidly connectable to the fluidic device by the flow control valve, and a common fluid buffer source fluidly connectable to the fluidic device by the flow control valve. The flow control valve permits flow comprising: (i) flow from the first reagent fluid reservoir to the fluidic device, (ii) flow from the common fluid buffer source to the fluidic device, (iii) flow from the fluidic device to the first fluid buffer reservoir, (iv) flow from the first reagent fluid reservoir to the fluidic device, and (v) flow from the first fluid buffer reservoir to the fluidic device.

The present invention relates to the field of biomedical technology and discloses a cartridge and a testing device. The cartridge comprises a sample lysis compartment, a first sample mixing compartment and a first PCR compartment; a first valve is disposed between the sample lysis compartment and the first sample mixing compartment, the first valve controls the flowing or blocking of the sample between the sample lysis compartment and the first sample mixing compartment; a fourth valve is disposed between the first PCR compartment and the first sample mixing compartment, the fourth valve controls the flow or blocking of the sample between the first sample mixing compartment and the first PCR compartment; a first reagent is provided in the first sample mixing compartment. In the compartment, nucleic acids in the sample mix with the first reagent and is then sent to the first PCR compartment for amplification.

The present invention aims to provide a fluid handling device which can be manufactured more conveniently, can easily open and close a channel, and can be miniaturized. The fluid handling device of the present invention includes: a first channel; a second channel; and a valve disposed between the first channel and the second channel, in which the valve includes: a groove-shaped valve seat disposed in a board, and a flat plate-shaped flexible layer covering the groove-shaped valve seat, and the valve communicates between the first channel and the second channel when the flat plate-shaped flexible layer and a bottom of the groove-shaped valve seat are spaced apart from each other, and blocks communication between the first channel and the second channel when the flat plate-shaped flexible layer and an inner wall of the groove-shaped valve seat are in contact with each other.

The present disclosure relates to a mechanism for fluidic sealing of a reaction cartridge in a reaction system using a single linear actuator. A single motion provided by the linear actuator is used to establish leak-resistant fluid communication between the reaction cartridge and two independent fluidic channels. The dual-sealing assembly described herein enables the use of fewer parts and a simpler control unit. The use of fewer parts and simpler control system allow for a very compact sealing mechanism and could also increase reliability, will be easier to manufacture as it will require less manufacturing testing and calibration, and is more tolerant of variance in the part being sealed (the reaction cartridge). In some embodiments, the reaction cartridge comprises a solid support matrix and a reaction reagent attached to the solid support matrix, and the reaction system is used for treating macromolecules, such as polypeptides, for sequencing and/or analysis.

A low-voltage microfluidic valve device and system for regulating the flow of fluid. One low-voltage microfluidic valve device for regulating the low of fluid includes a nano-textured dendritic metallic filament configured to grow and retract in response to a voltage. The low-voltage microfluidic valve device also includes a microfluidic channel configured to allow fluid flow, wherein the fluid flow is selectively interrupted by the growth of the nano-textured dendritic metallic filament. The low-voltage microfluidic valve device also includes a membrane positioned proximate to the fluid and configured to alter shape in response to the growth of the nano-textured dendritic metallic filament.

There is provided an arrangement (100) which allows for mixing a first fluid with a second fluid at a predetermined volume mixing ratio in a capillary driven fluidic system. The arrangement (100) allows filling an initially empty mixing chamber (110) with the first fluid. The arrangement then allows emptying a predetermined fraction of the first fluid from the mixing chamber (110) such as to form an empty space in the mixing chamber (110). The arrangement then allows filling the empty space of the mixing chamber (110) with the second fluid, thereby allowing a predetermined volume of the first fluid to mix with a predetermined volume of the second fluid over time.

There is provided a microfluidic device for reversing a flow through a microfluidic channel. The microfluidic device comprises a first microfluidic channel extending between a first inlet and a first outlet, a second microfluidic channel which fluidically connects a first point of the first microfluidic channel to a second outlet via a first valve, a third microfluidic channel which fluidically connects a second point of the first microfluidic channel to a second inlet via a second valve, the second point being located between the first point and the first outlet, and at least one circuit for opening the first valve and the second valve. The first and the second valves are arranged to be initially closed, Upon opening of the first and the second valve during use, the flow direction through the first microfluidic channel between the first point and the second point is reversed.

Provided herein is a valve manifold comprising (a) an elastomer sheet attached to a plurality of magnetic pistons, wherein the magnetic pistons project from a first side of the elastomer sheet; (b) a foot component comprising a first surface and a plurality of shafts that orthogonally pass through the first surface; and (c) a body component comprising a second surface, a groove that laterally passes along the second surface, and a plurality of reservoir channels that orthogonally pass through the second surface, wherein the elastomer sheet is compressed between the foot component and the body component.