The present invention relates to fluidic devices, especially microfluidic devices, for aliquoting and pairwise combinatorial mixing of a first set of liquids with a second set of liquids. The device architecture is designed to move liquids in two separate phases, a first phase where the liquids are exposed to a first directional force field to move the liquids in a first direction, from a reservoir to aliquot chambers, and a second phase where the liquids are exposed to a second directional force field to move the liquids in a second direction, from the aliquot chambers to the mixing chambers. The first and second directional force fields that the device is exposed to may be achieved using a single directional force field (i.e. a rotor driven centrifugal force field) and by re-orienting the position of the device with respect to the centrifugal forces between the first and second phases of operation. The device architecture comprises reservoirs for each of the first fluids and reservoirs for each of the second fluids. Each reservoir is fluidically connected to aliquoting chambers, either arranged in parallel or in series, for providing aliquots of the fluid which may be metered. The conduits providing fluid communication between the reservoirs and aliquoting chambers are arranged in a first direction. A series of mixing chambers is also provided, and each mixing chamber is fluidically connected to one aliquot chamber for a first liquid and one aliquoting chamber for a second liquid. The conduits providing fluid communication between the aliquoting chambers and mixing chambers are arranged in a second direction.

Accordingly, in some embodiments of the disclosure, a multi-chambered assay device is provided, which is configured for arrangement on a disc, as well as configured to process an individual sample. A plurality of such assay devices can be arranged along a periphery of the disc at a distance/radius from the center, such that a plurality of individual samples can be processed, e.g., one per assay device. In addition, in an arrangement that a plurality of assay devices are used, they can be spaced apart such that they balance the disc during rotation (which can be with samples contained in one or more of the assay devices, a plurality, a majority, or all of the assay devices).

Accordingly, in some embodiments of the disclosure, a multi-chambered assay device is provided, which is configured for arrangement on a disc, as well as configured to process an individual sample. A plurality of such assay devices can be arranged along a periphery of the disc at a distance/radius from the center, such that a plurality of individual samples can be processed, e.g., one per assay device. In addition, in an arrangement that a plurality of assay devices are used, they can be spaced apart such that they balance the disc during rotation (which can be with samples contained in one or more of the assay devices, a plurality, a majority, or all of the assay devices).

Devices and methods for handling liquids are provided. The devices and methods make use of specifically controlled centrifugal forces to drive liquid flow between two cavities connected by a conduit such that as liquid flows into the second cavity, a gas volume is trapped in the second cavity and a pressure of the gas increases, allowing for pneumatic control of liquid flow. The devices and methods facilitate one or more of the mixing, metering and sequencing of liquids, for example on a microfluidic device.

A fluidic centripetal apparatus for testing components of a biological material in a fluid is presented. The fluidic centripetal device is adapted to be received within a rotatable holder. The apparatus comprises a fluidic component layer having fluidic features on at least a front face and a bottom component layer bonded to a rear of the fluidic component layer thereby creating a fluidic network through which the fluid flows under centripetal force. In one embodiment, the fluidic feature may be a bottom-Tillable chamber coupled to an entry channel for receiving the fluid, the chamber inlet being provided at an outer side of the bottom-fillable chamber. In another embodiment, the fluidic feature may be a retention chamber coupled to an entry channel for receiving the fluid, a container wholly provided in the retention chamber and containing a liquid diluent, the container maintaining the liquid diluent in the container until it releases it in the retention chamber upon application of an external force to the container, thereby restoring the fluidic connection between the liquid diluent and the fluid in the retention chamber. Additionally, the retention chamber can have a flow decoupling receptacle for receiving the fluid, located at the outer side of the retention chamber and interrupting a fluidic connection between the entry and exit of the retention chamber. A test apparatus and a testing method using a fluidic centripetal device for testing components of a biological material in a fluid are also provided.

A sample analysis substrate in which transfer of a liquid is effected through rotational motions, including: a substrate having a rotation axis; a first retention chamber being located in the substrate and retaining a diluent; a measurement chamber being located in the substrate; at least one reagent; a reagent chamber being located in the substrate and having the at least one reagent disposed therein, the reagent chamber being connected to the measurement chamber; and a first diluent path being located in the substrate, and connecting the first retention chamber and the measurement chamber or reagent chamber.

A microfluidic device for evaluation of an organic/inorganic scale inhibitor is provided. The device comprises a substrate mountable to a disc for rotation about an axis. The device further comprises a proximal end and a distal end. The substrate defines a sample reservoir, a solvent reservoir, an inhibitor reservoir, and a precipitant reservoir at the proximal end and an analysis chamber at the distal end in fluid communication with the sample, solvent, inhibitor, and precipitant reservoirs. The substrate is constructed to direct one or more of fluids in the sample reservoir, solvent reservoir, inhibitor reservoir, and precipitant reservoir radially outwardly towards the analysis chamber under the influence of centrifugal force when the microfluidic device rotates.

An emulsification module for a food processor enables the careful and methodical introduction of ingredients (e.g., oil) into the main container, thus allowing the same to emulsify the ingredients. The emulsification module includes a container configured to be removably connected to, and rotate with, the rotating blade assembly, and one or more oil dispensers positioned on a side surface thereof. The centrifugal forces generated by the rotation of the blade assembly causes the oil in the container to be propelled up the inside walls of the same and come out of the oil dispensers and drizzle down the side walls of the main container. Whisk members positioned on the bottom of the module (between the blades of the blade assembly) assist in mixing of the drizzled oil with the ingredients to achieve the desired emulsification.

Devices and methods for handling liquids are provided. The devices and methods make use of centrifugal forces to drive liquid flow and facilitate one or more of the mixing, metering and sequencing of liquids, for example on a microfluidic device.

According to one or more aspects, a specimen processing method may use a cartridge comprising a chamber configured to store a liquid. The method may include: storing a specimen and a dispersion medium in the chamber of the cartridge; and rotating the cartridge about a rotational shaft to agitate the specimen and the dispersion medium in the chamber, to thereby form an emulsion in which a dispersoid containing the specimen is dispersed in the dispersion medium.