A microfluidic chip orients and isolates components in a sample fluid mixture by two step focusing, where sheath fluids compress the sample fluid mixture in a sample input channel in one direction, such that the sample fluid mixture becomes a narrower stream bounded by the sheath fluids, and by having the sheath fluids compress the sample fluid mixture in a second direction further downstream, such that the components are compressed and oriented in a selected direction to pass through an interrogation chamber in single file formation for identification and separation by various methods. The isolation mechanism utilizes external, stacked piezoelectric actuator assemblies disposed on a microfluidic chip holder, or piezoelectric actuator assemblies on-chip, so that the actuator assemblies are triggered by an electronic signal to actuate jet chambers on either side of the sample input channel, to jet selected components in the sample input channel into one of the output channels.

A heat sealing product suitable for seating one or more individual containers, said heat sealing product comprising: (i) a plurality of individual heat seals set out in a configuration substantially corresponding to the shape and configuration of the container(s) to be sealed, the size and shape of the individual heat seals corresponding substantially to the size and shape of the tops of the individual container(s) to be sealed; (ii) a peelable support film layer coated on one side with a low tack adhesive, the low tack adhesive serving to hold the individual heat seals in place on the support film layer in the desired configuration prior to the sealing process; (iii) alignment points in the sealing product adapted to enable the heat sealing product and therefore the individual heat seals of the heat sealing product to be aligned substantially exactly with respect to the individual containers to be sealed.

An apparatus includes a fluid reservoir and a laminate fluidic circuit positioned above the fluid reservoir. The laminate fluidic circuit includes two or more layers laminated together to define a substantially planar substrate and one or more channels defined within the substrate. The laminate fluidic circuit includes a flexible conduit defined by a portion of the substrate encompassing an extent of at least one of the channels that is partially separated or separable from the remainder of the substrate. The flexible conduit is deflectable with respect to the planar substrate toward the fluid reservoir such that the flexible conduit fluidly connects the at least one channel to the fluid reservoir.

The present invention relates to a biosensor technique in which multiple types of target substances (biomarkers) contained in saliva or the like are allowed to be simultaneously measured or N samples for one target substance (biomarker) are allowed to be simultaneously measured and reliability of sensed results and high sensitivity are secured. A fluidic channel-based planar biosensor chip, in which a plurality of fluidic channels capable of measuring target substances (biomarkers) are embedded in one flat plate sensor chip and the flat plate sensor chip is measured by a light-emitting element (optical source) and a light-receiving element, and a biomarker measuring apparatus using the same are provided.

A fluid device includes a substrate and a gas-liquid separating filter, the substrate has a flow path through which a solution flows, a reservoir, in which the solution is accommodated, connected to the flow path, an injection hole configured to connect the reservoir to the outside, and an air introduction hole branched off from the injection hole and connected to the outside, and the gas-liquid separating filter is disposed in a path of the air introduction hole, allows passage of a gas flowing through the air introduction hole, and prevents passage of a liquid flowing through the air introduction hole.

A microfluidic system is intended for the analysis of a biological sample containing biological species. The system includes an optical detection device having a source configured to emit an optical signal and at least one sensor having a capture surface defining an optical signal reading zone. The system also includes a microfluidic device having a support in which an amplification chamber, in which an amplification reaction can be carried out, is made, and having an input channel opening into the amplification chamber. The amplification chamber includes at least one first zone located in the sensor reading zone and at least one protuberance forming a recess intended to receive a compound for internal control of the amplification reaction and arranged to be located outside the sensor reading zone or configured to be opaque to said optical signal.

Systems, methods, and apparatuses are provided for self-contained nucleic acid preparation, amplification, and analysis.

A fluidic device for processing a fluid or species therein is described. The device comprises a 3D channel including an inlet for receiving a sample fluid and an outlet for outputting the sample fluid. The channel is adapted for guiding flow of the sample fluid in an axial direction from the inlet to the outlet. The channel includes at least two side walls. The device also has a controllable flow inducer having electrodes for inducing, when the sample fluid is flowing through the channel, a motion of the sample fluid in the channel in a plane substantially orthogonal to the axial direction. Along at least one of the side walls at least part of the electrodes are formed by alternatingly at least an electrically conducting portion, an electrically insulating portion and a further electrically conducting portion.

A method for moving an aqueous droplet comprising providing an electrokinetic device including a first substrate having a matrix of electrodes, wherein each of the matrix electrodes is coupled to a thin film transistor, and wherein the matrix electrodes are overcoated with a functional coating comprising: a dielectric layer in contact with the matrix electrodes, a conformal layer in contact with the dielectric layer, and a hydrophobic layer in contact with the confornial layer; a second substrate comprising a top electrode; a spacer disposed between the first substrate and the second substrate and defining an electrokinetic workspace; and a voltage source operatively coupled to the niatrix electrodes. The method further comprises disposing an aqueous droplet on a first matrix electrode; and providing a differential electrical potential between the first matrix electrode and a second matrix electrode with the voltage source, thereby moving the aqueous droplet.

A flow cell that includes (a) a gasket interposed between a first substrate and a second substrate, wherein the gasket, the first substrate and the second substrate are impermeable to aqueous liquid and liquid adhesive, wherein the gasket has a footprint on the first substrate that delineates a channel for containing the aqueous liquid; (b) a via in the gasket, the via containing a solidified liquid adhesive that bonds the first substrate to the second substrate, wherein the solidified liquid adhesive in the via is separated from the channel by the gasket; and (c) a channel port connecting the channel to the exterior of the flow cell, wherein the channel port is permeable to the aqueous liquid.