A second device includes a first surface, a second surface in contact with a first device, and a first hole extending through and between the first surface and the second surface and being continuous with a groove on the first device. A third device includes a third surface in contact with the first surface, a second hole open in the third surface and continuous with the first hole, and a flow path continuous with the second hole and open in the third surface. As viewed in a first direction from the first surface to the second surface, the first hole includes at least one vertex surrounded by the second hole, and a pair of sides joined to the at least one vertex and widening toward the flow path to define a minor angle.

A system, mixing-enhanced microfluidic container, and methods for small volume sample collection and/or analysis is disclosed. Namely, the invention is directed to a small volume sample collection system that includes a mixing-enhanced microfluidic container and a durable reusable actuation chuck. The mixing-enhanced microfluidic container is used to collect small volumes of sample fluid and includes a means for mixing the sample fluid with reagents disposed within the microfluidic container. The mixing means utilize an array of surface-attached structures (e.g., a micropost array). The application of an “actuation force,” such as a magnetic or electric field, actuates the surface-attached structures into movement, wherein the actuation chuck in close proximity to the mixing-enhanced microfluidic container provides the “actuation force.”

A liquid handling device includes: a cartridge including a first reservoir part in which a first reagent that is preservable in a non-frozen state is stored; and a channel chip including a second reservoir part in which a second reagent that should be preserved in a frozen state is stored, and a channel connected to the second reservoir part. The cartridge is attachable and detachable to and from the channel chip. The first reservoir part is connected to the channel when the cartridge is mounted in the channel chip.

A sensing system is disclosed. The sensing system includes a sensor cartridge and a readout device. The sensor cartridge includes a sensing device and a micro-channel-structure. The sensing device includes a chip member and an electrode member arranged projectively offset from each other.

A sperm sorting device suitable for selectively isolating motile sperms from a semen specimen includes a base and a sorting unit. The base comprises a central protruding block including a truncated cone-shaped surface, a bottom wall that surrounds the central protruding block, and an intermediate ring. The intermediate ring connects to the bottom wall via an inner wall surface. The sorting unit includes a sorting ring and a protruding ring. The sorting ring includes a central hole for a sorting filter that filters the semen specimen and is beveled at an angle that increases a permeable surface of the sorting filter. The protruding ring connects to the sorting ring via an inner sleeve surface. The sperm sorting device enhances sperm sorting quality by allowing the motile sperms to swim upward through the first sorting filter naturally.

A fluid handling system includes a fluid handling device including an opening for introducing a fluid or discharging the fluid; a tube including a flange, where one end of the tube is for connection to the opening, and the other end of the tube is for connection to an introduction device for supplying the fluid or to a discharge device for discharging the fluid; a support member including a first through hole into which the tube is inserted, and movably supporting the tube; and a first elastic member including a second through hole into which the tube is inserted, and holding a part of the tube while the first elastic member is in contact with the flange and the fluid handling device or the support member.

A system, configured to facilitate processing and detection of nucleic acids, the system comprising a process fluid container and a cartridge comprising: a top layer, a set of sample port-reagent port pairs, a shared fluid port, a vent region, a heating region, and a set of detection chambers; an intermediate substrate, coupled to the top layer comprising a waste chamber; an elastomeric layer, partially situated on the intermediate substrate; and a set of fluidic pathways, each formed by at least a portion of the top layer and a portion of the elastomeric layer, wherein each fluidic pathway is fluidically coupled to a sample port-reagent port pair, the shared fluid port, and a detection chamber, comprises a portion passing through the heating region, and is configured to be occluded upon deformation of the elastomeric layer, to transfer a waste fluid to the waste chamber, and to pass through the vent region.

A system for testing for an analyte includes a test strip. The test strip includes a first flow path. The test strip further includes a heating element in communication with a heating area of the first flow path, for heating a sample in the first flow path. The test strip further includes an e-gate, the e-gate in the first flow path, the e-gate separating the heating area from a detection area of the first flow path.

A microfluidic device comprises a cell flow layer and a control layer. The cell flow layer includes a growth channel, a collection channel, a plurality of bridge channels connecting the growth channel and the collection channel, a plurality of bridge valve portions, and a plurality of cell growth trenches coupled to the growth channel. The growth channel includes an inlet valve portion and an outlet valve portion controlling flow into and out of the growth channel. The collection channel includes an inlet valve portion and an outlet valve controlling flow into and out of the collection channel. The bridge valve portions control flow between the growth channel and the collection channel. The control layer includes a first control channel actuating the bridge valve portions and a second control channel actuating the inlet valve portions and the outlet valve portions of the growth channel and the collection channel.

Methods of selectively positioning a micro-object in a microfluidic device are described in this application. The microfluidic device can comprise an enclosure having an inlet, an outlet, and a flow region connecting the inlet and outlet, and an electrode activation substrate having a photoconductive layer. The methods of selectively positioning can comprising: projecting a first light beam on an electrode activation substrate of the microfluidic device, wherein the first position is proximal to the first micro-object, and wherein the first light beam activates a positive dielectrophoresis (DEP) force within the enclosure sufficient to capture the first micro-object; and projecting a second light beam upon a second position on the electrode activation substrate, wherein the second position is adjacent to or at least partially surrounding the first position, without overlapping the first position, the second light beam activating a positive DEP force within the enclosure sufficient to capture second micro-objects other than the first micro-object. The methods of selectively positioning can further comprise moving the first light beam towards a third position on the electrode activation substrate, wherein the DEP force activated by the first light beam is sufficient to move the first micro-object to the third position. Optionally, the methods can include moving the second light beam in relation to the first light beam to prevent micro-objects other than the first micro-object from being captured by the first light beam. Other embodiments are described.