The invention relates to a substrate for testing samples, in particular cells or molecules, wherein the substrate comprises a fluid system comprising a sample chamber configured in the substrate for storing and testing samples and at least one liquid reservoir in fluid communication with the sample chamber, and wherein the substrate comprises a passive blocking element capable of assuming a closed position and an open position, wherein in the closed position a fluid exchange between the sample chamber and the liquid reservoir is blocked.

A rotor assembly includes a rotor plate to rotate around a first axis, a bucket attached to the rotor plate and to rotate around a second axis, and a stop plate to rotate around the first axis between an open position and a closed position. When in the closed position, the stop plate engages the bucket to fix an angular position of the bucket relative to a plane of rotation of the rotor assembly. The rotor assembly further includes a housing for a sensor array component, the housing disposed in the bucket and including a solution inlet, a solution outlet, a transfer basin, a solution retainer disposed between the solution outlet and the transfer basin, and a collection reservoir in fluid communication with the transfer basin. The solution inlet and the solution outlet to engage ports of a flow cell of a sensor array.

A fluid handling device, comprising: a substrate including a first channel, a second channel and a partition wall formed between the first channel and the second channel; a film including a diaphragm, the film being disposed on the substrate so that the diaphragm faces the partition wall; and a sliding member slidable on the film while contacting with the film, the sliding member including a protrusion formed on an underside thereof, and the sliding member being disposed on the film with the underside facing the film, wherein: the sliding member is capable of switching between a first state and a second state by sliding on the film, wherein the protrusion is positioned so as not to face the partition wall with the diaphragm therebetween in the first state, and the protrusion is positioned so as to face the partition wall with the diaphragm therebetween in the second state.

An example microfluidic device comprises a plurality of fluidic channels and a fluidic multiplexor. The fluidic multiplexor includes a plurality of fluidic micro-valves fluidically coupled to the plurality of fluidic channels, and a plurality of control lines that cross the plurality of fluidic channels proximal to the plurality of fluidic micro-valves.

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 sealing valve 1 comprises a primary channel 2, a valve channel 4, and a geometry that permits liquid in the primary channel 2 to flow into the valve channel 4 through an inlet 5. Liquid in the primary channel 2 is inhibited from flowing through a first port 8 into the void volume 7. A meniscus 9 moved by a flow of liquid in the primary channel 2 is restrained at the first port 8. A flow of liquid through the primary channel 2 generates a capillary force that causes the flow of liquid to flow into the valve channel 4. A capillary force generated by the flow of liquid through the valve channel 4 causes the meniscus 9 to expand from the first port 8 into the primary channel, to inhibit flow of liquid in the primary channel 2 past the first port 8.

The present invention is directed to an apparatus and method of fabricating a sealed storage system for environmentally sensitive aqueous materials with liquid flow control and on-demand distribution. The present invention features a sealed storage apparatus capable of compactly containing a liquid reagent with liquid control capabilities. The apparatus may comprise a liquid-impermeable, air-impermeable, resistant to force-induced tearing pouch body capable of being penetrated through the application of a laser. The apparatus may further comprise a pouch cavity disposed within the pouch body for holding the liquid reagent. The apparatus may further comprise a liquid-impermeable, air-impermeable, and resistant to force-induced tearing sealing adhesive disposed over the pouch cavity to seal the liquid reagent within the pouch body capable of being penetrated through the application of the laser. Thus, the apparatus may allow liquid to flow from any point on the said apparatus by simply directing the laser to the point.

One aspect of this invention relates to a vertical-via rotary valve including a valve body having a housing; one or more fluidic channels, each fluidic channel having a vertical channel portion defined in the valve body and being adjacent to the housing, wherein a fluid flow through the vertical channel portion is controllable by deforming a sidewall of the vertical channel portion; and an actuator received in the housing and rotatably engaged with the one or more fluidic channels to operably control the fluid flow through the vertical channel portion of each fluid channel.

The invention relates to a device for synthesising oligonucleotides, comprising: a reagent container receptacle (1) for holding a reagent container support (17) comprising multiple reagent containers (18); an exchangeable microfluid chip (10) comprising a synthesis chamber, fluid connectors and microfluid valves; a control device (5); fluid connecting means (2); wherein the device can be loaded with the microfluid chip (10) and the reagent container support (17) when in a loading position; a chip receptacle (3). To allow cost-effective and prompt synthesis even of small amounts of oligonucleotides, the invention provides for an actuator device (6) to be provided, with which the reagent container receptacle (1), the microfluid chip (10) and the fluid connecting means (2) can be brought from the loading position to an operating position, in which operating position the reagent container receptacle (1), the chip receptacle (3) and the fluid connecting means (2) are positioned relative to each other such that reagents can be conveyed out of the reagent containers (18) towards the synthesis chamber (14) depending on the valve position of the microfluid valves.

A system, apparatus, and method include a pump to deliver vapor including airborne contaminants including organic compounds including a target analyte; a collector to transfer the airborne contaminants by autonomous liquid extraction into a mobile organic liquid phase; a micro-fluidic chamber including immobilized biorecognition elements that bind to analytes delivered from the mobile organic liquid phase; a mechanism to introduce the mobile organic liquid phase to a buffer containing a plurality of substrates causing a series of biochemical reactions that create a change corresponding to a concentration of the target analyte; and a detector to perform real-time analysis that correlates to a concentration of the organic compounds to determine a presence of the target analyte.