A single junction sorter for a microfluidic particle sorter, the single-junction sorter comprising: an input channel, configured to receive a fluid containing particles; an output sort channel and an output waste channel, each connected to the input channel for receiving the fluid therefrom; a bubble generator, operable to selectively displace the fluid around a particle to be sorted and thereby to create a transient flow of the fluid in the input channel; and a vortex element, configured to cause a vortex in the transient flow in order to direct the particle to be sorted into the output sort channel.

A device enables a user to detect biomarkers, and includes an element that defines a multiplicity of microfluidic channels that communicate between an inlet duct and an outlet duct, the inlet duct communicating with an inlet port into which a user can introduce a drop of body fluid; the outlet duct communicating with an outlet port. A resilient bladder is connected to the outlet port to provide suction. Each microfluidic channel defines a reaction chamber containing a biomarker-sensitive reagent which provides a color or a change of color in the presence of a biomarker, there being a multiplicity of different biomarker-sensitive reagents, one such biomarker-sensitive reagent being provided in each of the multiplicity of different microfluidic channels. At least part of the element is transparent so the color within the reaction chamber can be seen. The device includes a cover with magnifying lenses above the reaction chambers. The device may be used in conjunction with a smart phone.

The present invention provides devices and methods for generating a pulsatile fluid flow in a microchannel by means of external actuation of a thin flexible film. With the devices described herein, cycles of positive and negative actuation can be used to infuse or withdrawal fluid in a microchannel. Fluid can be recirculated over one or more microfluidic feature, such as a chemical or molecular receptor, biosensor, electrode, cell or biological material, chromatography feature, mixer, etc., in a way that would represent an advantage over the single-pass flow techniques common to most microfluidic devices. The devices and methods are particularly useful in vitro diagnostics (IVD), analytical chemistry, chromatography, and mixing applications in a variety of fields.

A lysis device including a sample vessel, at least one piezo element, and a controller is disclosed. The sample vessel has a microchannel formed therein. The sample vessel has at least one port extending through a surface to the microchannel. The piezo element is attached to the surface of the sample vessel. The controller has logic to cause the controller to emit a first signal including a series of frequencies to the at least one piezo element to cause the at least one piezo element to generate ultrasonic acoustic standing waves in the sample vessel, to receive a second signal indicative of measured vibration signals from the sample vessel detected by the at least one piezo element, and to determine a resonant frequency of the sample vessel using the measured vibration signals.

An immunoassay device for use in quantitatively measuring an amount of an analyte in a fluid sample, employs reagents that include particle pairs comprising a) one of an antigen and antibody coupled with a label, and b) a magnetic particle coupled with the other of the antigen and antibody. A transport which moves a set of reaction wells along a path and a dispenser dispenses respective ones of the reagents into the reaction wells. Prior to magnetic separation and optical analysis, a controller that coordinates movement of the transport with operation of the pipette modules operates the transport to reciprocate the set of reaction wells along the path for mixing the fluid sample with the reagents.

Techniques regarding one or more structures that can facilitate automated, multi-stage processing of one or more nanofluidic chips are provided. For example, one or more embodiments described herein can comprise a system, which can comprise a roller positioned adjacent to a microfluidic card comprising a plurality of fluid reservoirs in fluid communication with a plurality of nanofluidic chips. An arrangement of the plurality of nanofluidic chips on the microfluidic card can defines a processing sequence driven by a translocation of the roller across the microfluidic card.

A method for producing a liquid reaction mixture containing a radioisotope, in particular, a radioactive composition, minimizes device contamination with radioactive substances and increase speed and accuracy with which droplets are mixed. The method for producing a radioactive composition includes placing at least one first droplet L1 containing a radionuclide and at least one second droplet L2 containing a labeling substance on at least two respective dimples 5 among dimples 5 on a front surface 4b of an insulating layer 4 of a liquid manipulation device 1, and obtaining a liquid mixture M by using a change in electrostatic force caused by changing voltage applied to the electrodes 3 to thereby cause a relative movement between the at least one first droplet L1 and the at least one second droplet L2 so that the at least one first droplet L1 and the at least one second droplet L2 are mixed together at any one dimple among the dimples 5.

A digital microfluidic chip and a digital microfluidic system. The digital microfluidic chip comprises: an upper substrate and a lower substrate arranged opposite to each other; multiple driving circuits and multiple addressing circuits disposed between the lower substrate and the upper substrate; and a control circuit, electrically connected to the driving circuits and the addressing circuits. The control circuit is configured to apply, in a driving stage, a driving voltage to each driving circuit, such that a droplet is controlled to move inside a droplet accommodation space according to a set path, measure, in a detection stage, after a bias voltage is applied to each addressing circuit, a charge loss amount of each addressing circuit, and to determine the position of the droplet according to the charge loss amount. The charge loss amount of each addressing circuit is related to the intensity of received external light.

A microfluidic device in which microfluidic channels are embedded in a culture medium chamber and have open sides. The microfluidic device is patterned with a fluid moved along a hydrophilic surface due to capillary force, and the fluid may be rapidly and uniformly patterned along an inner corner path and a microfluidic channel. In the microfluidic device, the microfluidic channel is connected to facilitate fluid flow with a culture medium through open sides thereof and openings, and thus may provide a cell culture environment in which high gas saturation is maintained. In addition, several microfluidic devices formed on one common substrate are described. Such microfluidic devices may be manufactured of a hydrophilic engineering plastic by injection molding.

There is provided an assembly, useable to screen sample fluids for predefined molecules, the comprising, a needle unit comprising n hollow needles, wherein n is greater than one; a flow cell unit comprising m flow cells, wherein m is greater than one, each flow cell having an input and an output, and a test surface on which ligands can be provided; a first selector valve unit which is fluidly connected between the needle unit and flow cell unit, which is operable to selectively fluidly connect any one of the n hollow needles with the m flow cells in the flow cell unit; a pumping means which is selectively operable to provide negative pressure; a second selector valve unit which is fluidly connected between the pumping means and the output of each flow cell. There are further provided methods of screening sample fluids for predefined molecule.