Described herein are microfluidic devices and systems for high density cell culture and/or high throughput cell assays. Methods of using the same are also provided herein. In some embodiments, the microfluidic devices and systems described herein provide rapid and automated trapping of single embryos in ordered arrays.

Provided is a method of enclosing a microscopic body in at least some of a plurality of cavities formed in the surface of a substrate, including the step of arranging an insertion member above the cavity-formed surface of the substrate, determining relative positions of the insertion member and the substrate by a support section provided on the insertion member such that the bottom surface of the insertion member and the cavity-formed surface of the substrate face each other, thereby providing a solution introduction space between the bottom surface of the insertion member and the cavity-formed surface of the substrate, and providing a solution discharge space that is in communication with the solution introduction space, the solution discharge space being located above the bottom surface of the insertion member, and between the substrate and the insertion member, within the substrate and/or within the insertion member.

An example system includes an input channel having a first end and a second end to receive particles through the first end, a separation chamber, at least two output channels, and an integrated pump to facilitate flow through the separation chamber. The separation chamber is in fluid communication with the second end of the input channel. The separation chamber has a passive separation structure, the passive separation structure including an array of columns spaced apart to facilitate separation of particles in a flow based on a size of the particles. Each output channel is in fluid communication with the separation chamber to receive separated particles. The integrated pump is positioned within at least one of the input channel or one of the at least two output channels.

There is disclosed a fluid distribution system for distributing fluid from a single source to a plurality of downstream receptacles. The system has a distribution manifold with a single inlet and a plurality of outlets arrayed around a circumferential outer periphery. The outlets may be directed to the different receptacles which each have their own vent filter, or each receptacle connects back to the distribution manifold for common venting.

A device for manipulating microdroplets using optically-mediated electrowetting comprising: a first composite wall comprising: a first transparent substrate; a first transparent conductor layer on the substrate having a thickness of 70 to 250 nm; a photoactive layer activated by electromagnetic radiation in the wavelength range 400-1000 nm on the conductor layer having a thickness of 300-1000 nm; and a first dielectric layer on the conductor layer having a thickness of 120-160 nm; a second composite wall comprised of: a second substrate; a second conductor layer on the substrate having a thickness of 70 to 250 nm; and an A/C source to provide a voltage across the first and second composite walls connecting the first and second conductor layers; at least one source of electromagnetic radiation having an energy higher than the bandgap of the photoexcitable layer; and means for manipulating the points of impingement of the electromagnetic radiation on the photoactive layer.

A flow apparatus for detecting a component on a surface is provided. The flow apparatus, comprising an inlet for receiving a solution of the components to be detected; a detection chamber in fluid connection with and downstream from the inlet, and in fluid connection with a downstream outlet, wherein the internal surface of the detection chamber comprises a plurality of detection zones and the detection zones are configured to adhere to the component to be detected such that the component is immobilised in the detection zones; a detector for detecting components immobilised on each of the detection zones; and a director for directing the flow of the solution of the components to each of the detection zones in sequence, wherein the director is provided by flow rates.

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.

A field portable diagnostic apparatus uses a rotatable disk in which a microfluidic circuit is defined. The microfluidic circuit includes a centrifugal separation chamber receiving a sample to stratify the sample. A magnetic bead holding chamber is communicated to a mixing chamber, where mass amplifying functionalized magnetic-nanoparticles, held in a buffer solution and contained in the magnetic bead holding reservoir communicated to mixing chamber, are mixed with the separated fluid delivered to mixing chamber from the separation chamber. The functionalized magnetic nanoparticles conjugate with a target analyte in the sample. A magnet in proximity to a SAW chamber including a SAW detector draws the functionalized magnetic nanoparticles toward antibodies immobilized on the SAW sensor surface A wash reservoir is communicated to the SAW sensor chamber, and a cleanup/waste reservoir is communicated to the SAW chamber for receive fluid after it has passed through the SAW chamber.

The present invention relates to a cell culture device comprising at least a fluidic channel having at least a cell medium inlet and a cell medium outlet, said fluidic channel comprising a lower wall extending between the cell medium inlet and the cell medium outlet, the cell culture device further comprising at least one recess configured to receive a plurality of cells, said recess being formed by the lower wall and defining a bottom surface, and at least a cell trap, said cell trap being configured to capture a cell advected in the fluidic channel and then to make the cell sediment to the bottom surface of the recess.

Systems and methods for light based heating of light absorbing sources for modification of nucleic acids through fast thermal cycling of polymerase chain reaction are provided. The system includes a polymeric fluidic device comprising one or more reaction wells. A first light absorbing material is disposed on a first support to define a reaction well and first and second ports are coupled to the reaction wells. The first and second ports are configured to allow input of a fluidic sample into the reaction well. A lyophilized reagent is pre-loaded in the reaction well. A light source is configured to illuminate the first light absorbing material. A first portion of light illuminated onto the first light absorbing material is absorbed into the first light absorbing material and is configured to elevate the temperature of the first light absorbing material to heat the fluidic sample within the reaction well.