A particle sorting apparatus is provided. The particle sorting apparatus includes a first detector of a first scatter channel to detect a first light scatter generated by a particle flowing in a flow channel of a fluid sample and passing through a first laser beam, and a second detector of a second scatter channel to detect a second light scatter generated by the particle flowing in the flow channel of the fluid sample and passing through a second laser beam. The particle sorting apparatus also includes circuitry configured to output a first scatter pulse information and a first detection time of the first light scatter channel, a second scatter pulse information and a second detection time of the second light scatter channel. The first laser beam and the second laser beam are irradiated to the particle in different positions of the flow channel.

Control of fluid flow in a fluidic network is provided by controlling phase transitions of a phase-change material between a liquid phase and a non-fluid phase. The phase-change material is disposed at ports of the fluidic network where the fluidic network is in communication with an ambient. This advantageously provides control of pressure-driven flow within the fluidic network without altering properties of fluids within the fluidic network.

The present technology provides for an apparatus for detecting polynucleotides in samples, particularly from biological samples. The technology more particularly relates to microfluidic systems that carry out PCR on nucleotides of interest within microfluidic channels, and detect those nucleotides. The apparatus includes a microfluidic cartridge that is configured to accept a plurality of samples, and which can carry out PCR on each sample individually, or a group of, or all of the plurality of samples simultaneously.

A passive microfluidic valve includes a first manifold portion having a first chamber; a first inlet fluidly coupled to the first chamber; and a second inlet. The valve also includes a second manifold portion in fluid communication with the first chamber via a channel. The second manifold portion includes a second chamber fluidly coupled to the first chamber and the second inlet. The valve further includes a flexible membrane disposed between the first manifold portion and the second manifold portion and separating the first chamber and the second chamber, the flexible membrane configured to modulate a flow rate of a media flowing between the first inlet and the second inlet in either direction in response to pressure of the media flow.

A microfluidic device (100) for mixing a liquid L is provided. The microfluidic device (100) comprises a microfluidic chamber (20), having an inlet (30), and arranged to receive the liquid L therein. In use, the microfluidic device (100) is arranged to control translation through the liquid L of a body B introduced therein, wherein the translation of the body B is due to a potential field acting on the body. In this way, the controlled translation of the body B mixes the liquid L in the microfluidic chamber (20).

The present invention is directed to an improved fluid diode using topology optimization with Finite Element Method (FEM). Topology optimization as a flexible optimization method has been extended to the fluid field. For given boundary conditions and constraints, it distributes a specific amount of pores (or remove materials to get channel) in the design domain to minimize/maximize an objective function. In this design, inlet and outlet ports are aligned and inflow and outflow are in the same direction. The present invention features an intricate network of fluid channels having optimized fluid connectivity and shapes, which significantly improves the diodicity of fluidic passive valves.

A micro electrical mechanical system (MEMS) valve is provided. The MEMS valve includes first and second bodies, a medium and a thermal element. The first body defines a first channel and a second channel intersecting the first channel. The second body defines a third channel and is movable within the first channel between first and second positions. When the second body is at the first positions, the second and third channels align and permit flow through the second and third channels. When the second body is at the second positions, the second and third channels misalign and inhibit flow through the second channel. The medium is charged into the first channel at opposite sides of the second body. The thermal element is proximate to the first channel and is operable to cause the medium to drive movements of the second body to the first or the second positions.

The technology described herein generally relates to systems for extracting polynucleotides from multiple samples, particularly from biological samples, and additionally to systems that subsequently amplify and detect the extracted polynucleotides. The technology more particularly relates to microfluidic systems that carry out PCR on multiple samples of nucleotides of interest within microfluidic channels, and detect those nucleotides.

Microfluidic circuit elements, such as a microvalve, micropump or microvent, formed of a microcavity divided by a diaphragm web into a first subcavity bounded by a first internal wall and a second subcavity bounded by a second internal wall, where the diaphragm web is characterized as a thin film having a first state contacting the first internal wall and a second state contacting the second internal wall and exhibiting essentially no elasticity in moving between the first state and the second state, the thin film web having been stretched beyond its yield point before or during use are provided. The disclosed elements enable faster and more efficient cycling of the diaphragm in the microcavity and increases the diaphragm surface area. In a preferred embodiment, the microfluidic circuit element is pneumatically driven and controls the motion of fluids in a microassay device.

A portable vaporizing device and/or cartridge comprises a product chamber capable of holding a vaporizable product therein, and a porous valve element configured to be heated to flow the vaporizable product therethrough and generate vapor from the vaporizable product, and optionally including a heat transfer element to heat the vaporizable product as it flows through the product chamber towards the porous valve element.