The present invention relates broadly to production of a reagent on-board an instrument. The instrument is provided with a probe for dispensing said reagent, a concentrate chamber adapted to contain a concentrate and a diluent chamber adapted to contain a diluent. The probe includes an in-line mixing chamber adapted to receive the concentrate and the diluent to provide the reagent at the required concentration for dispensing by the probe.

An analyzing device has one end of a supplying capillary channel opened at a spot application section formed so as to protrude from an analyzing device main body. The supplying capillary channel is connected to a microchannel structure formed inside the analyzing device main body. A sample liquid is applied to the spot application section and is suctioned by a capillary force of the supplying capillary channel. The analyzing device is used for reading in which a suctioned solution is accessed. The analyzing device includes a leading end of the spot application section that has an inclined face. The end of the supplying capillary channel is opened on the inclined face.

A thermal convection generating device (1) that generates thermal convection of a liquid by heating or cooling the liquid and applying centrifugal force to the liquid, the thermal convection generating device including: a stage (20) to which a thermal convection generating chip (10) is attachable and detachable, the thermal convection generating chip including a disk-like substrate (11) and a thermal convection pathway (14) formed in a surface of the disk-like substrate that is perpendicular to an axis (AX) of the disk-like substrate, and being configured to rotate about the axis of the disk-like substrate to apply centrifugal force to a liquid in the thermal convection pathway; a heat controller (30) that heats or cools a portion of the thermal convection pathway; a motor (40) that drives the thermal convection generating chip to rotate about the axis; and a controller (50) that controls the heat controller and the motor.

Provided herein are passive microfluidic pumps. The pumps can comprise a fluid inlet, an absorbent region, a resistive region fluidly connecting the fluid inlet and the absorbent region, and an evaporation barrier enclosing the resistive region, the absorbent region, or a combination thereof. The resistive region can comprise a first porous medium, and a fluidly non-conducting boundary defining a path for fluid flow through the first porous medium from the fluid inlet to the absorbent region. The absorbent region can comprise a fluidly non-conducting boundary defining a volume of a second porous medium sized to absorb a predetermined volume of fluid imbibed from the resistive region. The resistive region and the absorbent region can be configured to establish a capillary-driven fluid front advancing from the fluid inlet through the resistive region to the absorbent region when the fluid inlet is contacted with fluid.

A flow cell for a dissolution test apparatus, Includes a cell mount, a filter head, a cylindrical cell casing connected with the cell mount and with the filter head via threads provided on respective ends of the cylindrical cell casing, and a sample cell received in the cell casing and co figured for receiving a sample.

A reagent management apparatus utilizing a flexible sheet that is foldable along scores into a disposable liner which may be freestanding via a three point structure. The disposable liner includes a reservoir for reagents and allows the pouring off of unused reagent into a storage container. The disposable liner may be used with a permanent base in certain cases.

Compositions, devices, and methods are disclosed for the modification of polymer surfaces with coatings having a dispersion of silicone polymer and hydrophobic silica. The surface coatings provide the polymer surface with high hydrophobicity, as well as increased resistance to biofouling with proteinaceous material. The polymer surfaces can be particularly useful in microfluidic devices and methods that involve the contacting of the covalently modified polymer surfaces with emulsions of aqueous droplets containing biological macromolecules within an oil carrier phase.

A fluidic device includes an impermeable base, single-strand walls coupled to the impermeable plate. The single-strand walls include a plurality of loops, each loop has a lower part of a double wedge and an upper part of a double wedge aligned with the lower part of the double wedge. The device also includes a lattice connected to the single-strand wall with a loop-as-wipe connection and a gabbled roof disposed opposite the impermeable base and coupled to the tops of the single-strand walls.

A microfluidic product utilizing gradient surface energy coatings for fluid control comprising a plurality of fluid passages wherein at least one fluid passage comprises a coating configured to control liquid flow wherein the coating configured to control liquid flow comprises a gradient surface energy coating from a proximal location to a distal location on a surface of the fluid passage. The product can include uniform regions and surface gradient regions in the same passage. Coating compositions and product dimensions can be selected to provide control over different flow properties including fluid velocity, reduction and acceleration of fluid flow, and starting and stopping fluid flow.

A fluidic device (10) is described. The fluidic device (10) comprises the first part (110) and the second part (120). The first part (110) comprises a first inlet (111) and a first outlet (112), mutually spaced apart. The second part (120) comprises a first chamber (121) arranged to contain a predetermined first amount A1 of a first fluid F1 therein and a first wall portion (122) arranged to contain, at least in part, the first fluid F1 in the first chamber (121). The fluidic device (10) is arrangeable in a first configuration, wherein the first part (110) is fluidically isolated from the first chamber (121). The fluidic device (10) is arrangeable in a second configuration, wherein the first inlet (111) and the first outlet (112) are fluidically coupled via the first chamber (121), whereby increasing a first pressure P1 in the first chamber (121) via the first inlet (111) urges at least a part of the predetermined first amount A1 of the first fluid F1 through the first outlet (112).