Apparatus for processing life-based organic particles, including particles selected from the list comprising cells, cellular spheroids, tissues, eukaryotes, micro-organisms, organs or embryos, comprises a hollow volume (10) that (a) is internally divided into at least first (14), second (16) and third (17) sub-volumes by at least two phaseguides (12, 13) formed inside the volume and (b) includes parts that are relatively upstream and relatively downstream when judged with reference to the movement of a meniscus or a bulk liquid in the volume (10). The apparatus includes at least first, second and third fluid conduits (19, 21, 22) connected to permit fluid communication between the upstream exterior of the volume (10) and a respective said sub-volume (14, 16, 17); and at least one further conduit (24) connected to permit fluid communication between the downstream exterior of the volume (10) and a said sub-volume. The first sub-volume (14) contains one or more life-based particles supported in or by a gel or gel-like substance; and the second sub-volume (16) communicates with the first sub-volume so as to permit transport of substances between the first and second sub-volumes (14, 16) and contains at least one gel or gel-like substance.

Method for handling at least one first microdrop and at least one second microdrop in a microfluidic system including a capillary trap that has a first trapping zone and a second trapping zone, the method including steps consisting of: (i) trapping the first microdrop in the first trapping zone, and (ii) trapping the second microdrop in the second trapping zone, the first and the second trapping zone being arranged such that the first and the second microdrops are in contact with each other, the first and the second trapping zones being adapted such that the trapping forces returned to one of the microdrops are different.

A fluidic device for mixing a reagent fluid with a fluid sample comprises a supply channel having a reagent inlet, a sample inlet and a first reagent storage, coupled to the supply channel; a mixer for mixing the reagent with the fluid sample, having a mixer inlet coupled to the supply channel at a position in between the sample inlet and the first reagent storage; In a first stage, when the reagent fluid is supplied in the reagent inlet, the reagent is provided in the supply channel and the first reagent storage, and such that the reagent is thereafter stationed in the supply channel and the first reagent storage until a fluid sample is provided in the sample inlet. When the fluid sample is supplied in the sample inlet, the supplied fluid sample and the stationed reagent flows into the mixer thereby mixing both fluids.

Provided herein are methods, compositions, and devices for the parallel handling of samples, such as cells or other biological samples. The methods, compositions, and devices are suited for multiple levels of analysis, including genetic and functional assays, of samples.

The invention relates to a pressure driven microfluidic chip for delivering a first liquid at a determined flow rate, said chip comprising a first inlet, a container connected to the first inlet, a second inlet connected to the container via a first passage, a second passage connecting the container to an outlet, wherein the first passage has a first resistance to liquid flow, and the second passage has a second resistance to liquid flow. The first resistance may be higher than the second resistance. The invention also relates to a pressure driven method of delivering a first liquid at a determined flow rate comprising using a chip first a first and second passage, wherein the first passage has a first resistance to the flow of the first liquid, and the second passage has a second resistance to flow of the second liquid.

Apparatus for processing life-based organic particles, including particles selected from the list comprising cells, cellular spheroids, tissues, eukaryotes, micro-organisms, organs or embryos, comprises a hollow volume (10) that (a) is internally divided into at least first (14), second (16) and third (17) sub-volumes by at least two phaseguides (12, 13) formed inside the volume and (b) includes parts that are relatively upstream and relatively downstream when judged with reference to the movement of a meniscus or a bulk liquid in the volume (10). The apparatus includes at least first, second and third fluid conduits (19, 21, 22) connected to permit fluid communication between the upstream exterior of the volume (10) and a respective said sub-volume (14, 16, 17); and at least one further conduit (24) connected to permit fluid communication between the downstream exterior of the volume (10) and a said sub-volume. The first sub-volume (14) contains one or more life-based particles supported in or by a gel or gel-like substance; and the second sub-volume (16) communicates with the first sub-volume so as to permit transport of substances between the first and second sub-volumes (14, 16) and contains at least one gel or gel-like substance.

An open-channel microfluidic diode includes a first reservoir, a second reservoir, a first channel and a second channel. The first channel is in fluid communication with the first reservoir, wherein the first channel is characterized by a first cross-sectional area. The second channel is in fluid communication with the first channel and the second reservoir, wherein the second channel is characterized by a second cross-sectional area greater than the first cross-sectional area. The first channel interacts with the second channel at a junction, and wherein liquid flows from the second channel to the first channel via capillary forces.

The present disclosure is directed to opposables including a body having a plurality of cavities disposed therein. Each cavity can be designed to contain one or more reagents, liquids, or fluids which may be applied to a specimen-bearing surface. In some embodiments, the cavities include one or more reagent chambers, the reagent chambers can have one or more seals such that the reagents, liquids, or fluids contained therein may be stored and released to the specimen-bearing surface.

A fluidic device for mixing a reagent fluid with a fluid sample comprises a supply channel having a reagent inlet, a sample inlet and a first reagent storage, coupled to the supply channel; a mixer for mixing the reagent with the fluid sample, having a mixer inlet coupled to the supply channel at a position in between the sample inlet and the first reagent storage; In a first stage, when the reagent fluid is supplied in the reagent inlet, the reagent is provided in the supply channel and the first reagent storage, and such that the reagent is thereafter stationed in the supply channel and the first reagent storage until a fluid sample is provided in the sample inlet. When the fluid sample is supplied in the sample inlet, the supplied fluid sample and the stationed reagent flows into the mixer thereby mixing both fluids.

The invention generally relates to microfluidic devices that include orthogonally positioned channels that are slidable relative to each other and methods of use thereof. In certain embodiments, the invention provides a microfluidic device that includes a first channel having an open end, and an open second channel. The first and second channels are slidable relative to each other such that when the open end of the first channel and the open portion of the open second channel are aligned with each other, fluid flows from the first channel into the second channel.