The present disclosure relates to a microfluidic circuit comprising an inlet port; an outlet port; a main channel fluidically connecting the inlet port and the outlet port; and a series of microchambers of differing volumes disposed within the main channel, where each microchamber is individually fluidically connected to the main channel via individual microchamber openings. The present disclosure also relates to a microfluidic device comprising a support layer; a substrate layer disposed on the support layer; and one or more microfluidic circuits of the present disclosure, where the one or more circuits are disposed within the substrate layer. Also disclosed is a method for performing an assay.

A device for separating blood plasma from whole blood includes a first reservoir and a second reservoir. The first reservoir is configured to receive a sample of whole blood including red blood cells and includes a collection region and a constricted region. The second reservoir is fluidically connected to the constricted region of the first reservoir, such that, responsive to centrifugal force applied to the device, the sample of whole blood disposed within the first reservoir separates into a first fraction and a second fraction. The first fraction is located in the collection region and includes blood plasma from which substantially all red blood cells have been removed. The second fraction is located in the second reservoir and includes blood plasma and red blood cells that have been removed from the first fraction by the centrifugal force. The constricted region inhibits the second fraction from entering the collection region.

Assay cartridges are described that have purification, reaction, and detection zones and other fluidic components which can include sample chambers, waste chambers, conduits, vents, reagent chambers, reconstitution chambers and the like. The assay cartridges are used to conduct multiplexed nucleic acid measurements. Also described are kits including such cartridges, methods of using the same, and a reader configured to analyze an assay conducted using an assay cartridge.

The present invention relates to a container for centrifugation. The container for centrifugation includes: a main body (100) including a first chamber (110) in which a material to be centrifuged is received, a second chamber (120) in which a suspended material centrifuged from the material in the first chamber (110) is decanted from the first chamber (110) and received and which is positioned on one side of the first chamber (110), and a coupling part (130) formed to surround the first chamber (110) and the outside of the upper end of the second chamber (120); and a cover (200) which covers an upper portion of the main body (100) and forms a fluid communication path (P) of the decanted suspended material between the first chamber (110) and the second chamber (120).

A microfluidic chip assembly having a plurality of microfluidic flow channels is provided. Each channel has a switching region. The microfluidic chip may further include at least one bubble jet actuator configured to generate a pressure pulse in the switching regions of the channels to selectively deflect particles in the flow. The bubble jet actuator may be configured as a blind chamber, as an operative non-through flow chamber and/or as a self-replenishment chamber. The bubble jet actuator may include a trapped air bubble. The bubble jet actuator may include a plurality of heating elements individually controlled for pre-nucleation warmup and/or for triggering vapor bubble nucleation.

A MEMS-based particle manipulation system which uses a particle manipulation stage and optical confirmation of the manipulation. The optical confirmation may be camera-based, and may be used to assess the effectiveness or accuracy of the particle manipulation stage. In one exemplary embodiment, the particle manipulation stage is a microfabricated, fluid valve, which sorts a target particle from non-target particles in a fluid stream. The optical confirmation stage is disposed in the microfabricated fluid channels at the input and output of the microfabricated sorting valve. Deep learning techniques are brought to bear on the camera output to increase speed, accuracy and reliability.

A pressure regulator module for a chip-based microfluidic platform is provided. The module includes a microfluidic channel for passing flowable material from the inlet region through the outlet region and into a downstream compartment; one or more microvalves fluidly connected to the microfluidic channel and upstream of the outlet region; and one or more reservoirs fluidly connected to the microvalves, for receiving flowable material diverted by the microvalves, where a flow of flowable material passing from the inlet region toward the downstream compartment is at least partially diverted by the microvalves into the reservoirs as a result of a pressure increase in the microfluidic channel. In some versions, the microvalves are capillary burst valves. A microfluidic chip containing the module and a method of using the module are provided.

Microfluidic structures and methods for manipulating fluids and reactions are provided. Such structures and methods may involve positioning fluid samples, e.g., in the form of droplets, in a carrier fluid (e.g., an oil, which may be immiscible with the fluid sample) in predetermined regions in a microfluidic network. In some embodiments, positioning of the droplets can take place in the order in which they are introduced into the microfluidic network (e.g., sequentially) without significant physical contact between the droplets. Because of the little or no contact between the droplets, there may be little or no coalescence between the droplets. Accordingly, in some such embodiments, surfactants are not required in either the fluid sample or the carrier fluid to prevent coalescence of the droplets. Structures and methods described herein also enable droplets to be removed sequentially from the predetermined regions.

Techniques regarding nanofluidic chips with a plurality of inlets and/or outlets in fluid communication with one or more nanoDLD arrays are provided. For example, one or more embodiments described herein can comprise a nanoscale deterministic lateral displacement array between and in fluid communication with a global inlet and a global outlet. The nanoscale deterministic lateral displacement array can further be between and in fluid communication with a local inlet and a local outlet. Also, the nanoscale deterministic lateral displacement array can laterally displace a particle comprised within a sample fluid supplied from the global inlet to a collection region that directs the particle to the local outlet. An advantage of such an apparatus can be the expanded versatility of the nanoscale deterministic lateral displacement array for sample preparation applications involving nanoparticles not accessible to other higher throughput microscale microfluidic technologies.

Described herein are multimodal test cards. The test cards include a shared architecture with interchangeable test zones. The test cards are particularly useful for diagnostic testing.