A system for mimicking a blood vessel of a patient includes a microfluidic device including a body and a microfluidic channel formed in the body, wherein the microfluidic channel includes a fluid inlet and a fluid outlet, and a coating formed on the microfluidic channel including a plurality of blood outgrowth endothelial cells (BOECs) isolated from the patient and which define an inner surface of the microfluidic channel.

A microfluidic device for detecting a target gene according to the present invention comprises a plurality of capillary tubes which are partially immersed in a sample container containing sample solution and in which the sample solution flows by capillary phenomenon, and microbead packings arranged at one part in each capillary tube to be arranged on a flow path of the sample solution, wherein each of the microbead packings comprises: a packing tube arranged at the capillary tube so as to partially constitute the flow path of the sample solution, a plurality of microbeads contained in the packing tube and being in close contact with each other to form voids between the microbeads, and probe linkers formed on a surface of each microbead, wherein the probe linkers are configured to amplify a target gene in the sample solution by complementary bonding with the target gene, thereby detecting the target gene.

A fluid refining device comprises at least two obstructions adapted to be facing with a front in an upstream direction towards an incoming fluid and a base edge opposite of the front, and a fluid outlet arranged at the base edge.

A microfluidic device may include an inlet, an outlet, first and second channels arranged in parallel, a first sensor pair positioned along the first channel, and a second sensor pair positioned along the second channel. The first channel may include a first upstream zone, a first downstream zone, and a first constriction zone. The second channel may include a second upstream zone, a second downstream zone, and a second constriction zone. The first sensor pair may include a first entry sensor configured to detect a first cell flowing through the first upstream zone, and a first exit sensor configured to detect the first cell flowing through the first downstream zone. The second sensor pair may include a second entry sensor configured to detect a second cell flowing through the second upstream zone, and a second exit sensor configured to detect the second cell flowing through the second downstream zone.

A method of digital quantification of a species in an EWOD device includes inputting a sample volume and a diluent volume into the EWOD device; performing an electrowetting operation to generate a first sample droplet from the sample volume; performing an amplification process on the first sample droplet and measuring a turn-on value for the sample droplet; comparing the measured turn-on value to a target turn-on value for digital quantification; calculating a dilution factor based on the comparison of the measured and target turn-on values; performing an electrowetting operation to extract a second sample droplet from the sample volume; performing an electrowetting operation to dilute the second sample droplet with the diluent volume by the dilution factor to form a diluted second sample droplet; and performing a digital quantification on the diluted second sample droplet to quantify an initial concentration of the species in the sample volume.

The present disclosure relates to analytical testing devices comprising microfluidics and methods for performing an assay on a fluid sample received within the microfluidics, and in particular, to mitigating drift of fluid samples over a sensor by incorporating a bypass channel into the microfluidics. For example, a test cartridge device is provided that includes a fluid sample entry port and holding chamber connected to a bifurcation junction of a sensor channel and a bypass channel. The sensor channel includes an upstream region and a downstream region, and an analyte sensor is in the upstream region. As a cross-sectional area of the bypass channel is greater than the cross-sectional area of the downstream region of the sensor channel, the bypass channel is a preferred path for excess sample flow and pressure, and thus sample drift above the analyte sensor is mitigated.

Embodiments of the invention are directed to a microfluidic device. The device comprises a flow path structure that includes an inlet microchannel and chambers. The flow path structure is configured as an arborescence extending from the inlet microchannel to the chambers. Thus, liquid introduced in said inlet microchannel can potentially enter the chambers via respective flow paths to remain essentially confined in the chambers, in operation. The device further comprises substances in selected ones of the chambers. That is, a subset of the chambers is loaded with substances adapted for interacting with liquid to yield a detectable change in a property of the liquid and/or the substance in each of the chambers of said subset, in operation. The invention is further directed to related devices, and methods of operation and conditioning.

The invention provides a passive fluidics circuit for directing different fluids to a common volume, such as a reaction chamber or flow cell, without intermixing or cross contamination. The direction and rate of flow through junctions, nodes and passages of the fluidics circuit are controlled by the states of upstream valves (e.g. opened or closed), differential fluid pressures at circuit inlets or upstream reservoirs, flow path resistances, and the like. Free diffusion or leakage of fluids from unselected inlets into the common outlet or other inlets at junctions or nodes is prevented by the flow of the selected inlet fluid, a portion of which sweeps by the inlets of unselected fluids and exits the fluidics circuit by waste ports, thereby creating a barrier against undesired intermixing with the outlet flow through leakage or diffusion.

Provided is a liquid droplet collection device including: a substrate having a hydrophobic surface; and a hydrophilic channel arranged in the hydrophobic surface, wherein the hydrophilic channel includes: a first-generation channel including a plurality of tapered channel portions radially extending from an origin point and monotonically tapering with increasing distance from the origin point; and a second-generation channel that includes a plurality of tapered channel portions radially extending from an origin point and monotonically tapering with increasing distance from the origin point, and is scaled down in size as compared to the first-generation channel, wherein the second-generation channel is joined to the first-generation channel to face the same direction as the first-generation channel, and wherein one of the tapered channel portions of the second-generation channel overlaps a distal end portion of one of the tapered channel portions of the first-generation channel, and the hydrophilic channel monotonically tapers from a proximal end of one of the tapered channel portions of the first-generation channel to a distal end of one of the tapered channel portions of the second-generation channel.

Methods for separating cells from a sample (e.g., separating fetal red blood cells from maternal blood) include introducing a sample including cells into one or more microfluidic channels. In one embodiment, the device includes at least two processing steps. For example, a mixture of cells is introduced into a microfluidic channel that selectively allows the passage of a desired type of cell, and the population of cells enriched in the desired type is then introduced into a second microfluidic channel that allows the passage of the desired cell to produce a population of cells further enriched in the desired type. The selection of cells is based on a property of the cells in the mixture, for example, size, shape, deformability, surface characteristics (e.g., cell surface receptors or antigens and membrane permeability), or intracellular properties (e.g., expression of a particular enzyme).