A microfluidic chip is disclosed herein. In a specific embodiment, the microfluidic chip comprises at least one microfluidic reservoir having a wall portion and a heat transfer sealing layer cooperating with the wall portion for receiving a sample to be tested. The heat transfer sealing layer is arranged to be contiguous with the sample to be tested. The microfluidic chip further comprises an active temperature control device arranged to provide structural support to the heat transfer sealing layer and operable to control a temperature of the sample via transmission of heat through the heat transfer sealing layer. A detection module is also disclosed.

A microfluidic device is disclosed which comprises a main flow channel and a partition chamber connected to a portion of same by a chamber inlet and chamber outlet. The device utilizes select cross sections to advantage capillary effects during filling and partitioning steps to isolate biological or other samples in the partition chamber for analysis and can be employed in a digital array.

A device for performing an assay comprises a tube, a cap, an insert, and a reaction container. The tube includes a lateral flow strip disposed therein. The cap is coupled to the tube and includes a hollow interior defined at least partially therethrough. The insert is configured to be at least partially received within the hollow interior of the cap. The reaction container includes a cavity configured to store one or more fluids therein, and is rotatably coupled to the cap such that rotation of the cap relative to the reaction container causes (i) mixing of the one or more fluids and (ii) at least a portion of the mixed fluids to be delivered from the reaction container to the lateral flow strip via the insert.

A microfluidic sensing assembly may include a first structure supporting a sensor array, a second structure joined to the first structure and forming a microfluidic passage and a flat lens to focus light, following reflection of the light back and forth across the microfluidic passage, from the microfluidic passage onto the sensor array.

In an amplification reaction in a microfluidic apparatus, the reaction is carried out using starting substances tagged with fluorophore and quencher. The detection of reaction products occurs according to the disclosure by a separation of fluorophore and quencher occurring in the context of the amplification reaction. For the detection reaction, at least one energy-transferring substance is added and the evaluation occurs on the basis of the fluorescence emission of the fluorophores which occurs.

A fluidic device having first side and second side. The fluidic device includes first latch mechanism and second latch mechanism for receiving connector, arranged on first side; and a first fluidic chip holder and second fluidic chip holder, arranged on first side in alignment with first latch mechanism and second latch mechanism, for holding first fluidic chip and second fluidic chip, respectively. The fluidic device includes a traction surface to couple the fluidic device with an actuator to move the fluidic device to select which of first or second fluidic chip is to be used. Disclosed is an apparatus with a container, tubular material feeding line, tubular printing composition feeding line, and actuator.

A microfluidic reaction chamber with a reaction chamber circuit includes a microfluidic reaction chamber to contain a reaction fluid for amplification of nucleic acids, and a reaction chamber circuit disposed within the microfluidic reaction chamber. The microfluidic reaction chamber includes a base wall, a top wall parallel to the base wall and defined in part by a transparent lid, a first side wall, and a second side wall. The reaction chamber circuit is disposed within the microfluidic reaction chamber, and includes a top surface, a bottom surface, a first side wall, and a second side wall. The reaction chamber circuit is in fluidic contact with the reaction fluid and includes a photodetector to detect a fluorescence signal from a labeled fluorescent tag in the reaction fluid.

A tunable inertial sheathing (TIS) system and methods for particle-size-insensitive high-throughput single-stream focusing of particles suspended in a particle-carrying fluid are provided. The TIS conditions particles to distribute locally within one of compartments of inertial force field, followed by an inertial focusing to migrate it to a single foci. For the particle localization, the TIS system introduces an arbitrary form of peripheral sheathing by generating and accumulating sheath fluid from particle-carrying fluid through a combination of inertial focusing, channel bifurcation and channel confluence. Multiple forms of the TIS system are also provided, each including one main channel and at least one bypass channel. The main channel includes and cascades at least three segments, at least one bifurcating junction and at least one confluence junction.

The single-use disposable spectrophotometer described herein can measure one or more blood chemistry analytes from a drop of whole blood. A passive filtration system takes whole blood and delivers plasma along with a dissolved reporter molecule to one or more spectrophotometers which can operate with narrow band optical spectrum centered on an optical detection frequency. The spectrophotometer detects the changes in absorption of the plasma as a result of a chemistry reaction to determine the concentration or activity of one or more analytes.

Fluid storage containers and analysis cartridges for use in assay processes are presented. In addition, systems comprising such storage containers and analysis cartridges and methods of using such containers and cartridges are presented as well. In specific embodiments, fluid storage containers are configured to be coupled to analysis cartridges in a first stage and a second stage.