Assay cartridges are described that have a detection chamber, preferably having integrated electrodes, and other fluidic components which may include sample chambers, waste chambers, conduits, vents, bubble traps, reagent chambers, dry reagent pill zones and the like. In certain embodiments, these cartridges are adapted to receive and analyze a sample collected on an applicator stick. Also described are kits including such cartridges and a cartridge reader configured to analyze an assay conducted using an assay cartridge.

A fluid delivery device includes at least one area onto which at least one support element having at least one well may be placed in a defined position. The fluid delivery device further includes at least one pipetting device having a connector configured to releasably connect the at least one pipetting device with a disposable tip and with a fluid displacement element which enables aspiration and ejection of a defined volume of liquid to or from the disposable tip. The at least one pipetting element is movable in a vertical and preferably in at least one horizontal direction. The fluid delivery device also includes a blowing element that has at least one aperture coupled to a source of pressurized gas and is movable in a vertical and preferably at least one horizontal direction. A system includes such a fluid delivery device and the at least one support element.

A method for analyzing biological samples is disclosed herein. In an embodiment, the method includes receiving a fluid sample into a cartridge device, which comprises: a fluidic chamber; at least one microfluidic channel in fluid communication with the fluidic chamber; and a venting port configured to apply a pneumatic force to the fluidic chamber; and inserting the cartridge device into a reader device to perform measurements, wherein the cartridge device is positioned in a vertical or tilted position such that at least a portion of the fluid sample inside the fluidic chamber is pulled by gravity in a direction away from the venting port or towards the bottom of the fluidic chamber.

An open microfluidic system is provided. The open microfluidic system including the extreme wettability of exclusive liquid repellency (ELR), open microchannels with high lateral resolution and low profile, various valve arrangements, capable of a broad range flow rates, and capable of spatially and temporally trapping particles in open fluid.

There is provided a microfluidic device for reversing a flow through a microfluidic channel. The microfluidic device comprises a first microfluidic channel extending between a first inlet and a first outlet, a second microfluidic channel which fluidically connects a first point of the first microfluidic channel to a second outlet via a first valve, a third microfluidic channel which fluidically connects a second point of the first microfluidic channel to a second inlet via a second valve, the second point being located between the first point and the first outlet, and at least one circuit for opening the first valve and the second valve. The first and the second valves are arranged to be initially closed, Upon opening of the first and the second valve during use, the flow direction through the first microfluidic channel between the first point and the second point is reversed.

Aniosotropic Ratchet Conveyor (“ARC”)-based biomolecule processing devices and related methods are described. The ARC-based biomolecule processing devices include (i) a substrate having an ARC track defined on or within the substrate and including a biomolecule receiving area, which is designed to receive biomolecule, and a reconstituting area, which is designed to contain dry reagents and is designed to receive a transport solution such that at the reconstituting area, dry reagents are reconstituted with transport solution; and (ii) a microheater area disposed at or near the biomolecule receiving area, fitted with a microheater, which is designed to heat biomolecule that is received through the biomolecule receiving area and designed to process heated biomolecule and dry reagents reconstituted with transport solution. The ARC track includes an arrangement of a plurality of hydrophilic rungs disposed on a hydrophobic region such that between consecutive hydrophobic rungs, a portion of the hydrophobic region is exposed.

Embodiments of the present disclosure are directed to methods, systems and devices, for precise and reduced spot-size capabilities using a laser to alter surfaces without chemical treatment, chemical waste, or chemical residues is provided for microfluidic systems (e.g., lab-on-a-disk, for example). In some embodiments, hydrophobic and super-hydrophilic areas can be created on surfaces in the same material at different areas and positions merely by using different laser settings (e.g., spot size, wavelength, spacing, and/or pulse duration). Accordingly, capillary forces that are a recurrent issue in a microfluidic devices (e.g., a centrifugal microfluidic disk) can be controlled for practical applications, including, for example when users handle the disks and insert a sample, the moment the substrate/device (e.g., disk) is placed in a system (e.g., a centrifugal system), capillary forces can take place and move the fluids, which becomes a problem for sequential bioassays taking place in substrate/device (e.g., disk). Thus, in some embodiments, the systems, devices and methods increase fluid control in microfluidic devices.

A novel microfluidic chip is proposed for performing a chemical or biochemical test in a metered reaction volume. The microfluidic chip has a body which defines an inner flow volume. An inlet has been provided to the body for connecting the inner flow volume to the ambient space. A waste channel forms part of the inner flow volume and is in fluid communication with the inlet. A sample channel also forms part of the inner flow volume and is in fluid communication with the inlet. The sample channel includes a first hydrophobic stop and a second hydrophobic stop at a distance from the first hydrophobic stop so as to provide a metered reaction volume there between. An expelling channel is in fluid communication with the metered reaction volume of the sample channel through the first hydrophobic stop. A sample reservoir is in fluid communication with the metered reaction volume of the sample channel through the second hydrophobic stop.

Various embodiments of fluidic devices and methods of the present teaching can provide precision on-device loading of fluidic samples, and merging, mixing, and splitting of the fluidic samples, in illustrative embodiments as droplets, using pressures that can be provided by standard laboratory liquid handling equipment. Various embodiments of fluidic devices of the present teachings can provide on-device manipulation of accurate and precise fluidic volumes at the picoliter to nanoliter scale for each steps from fluidic sample loading to fluidic sample splitting. Various embodiments of fluidic elements of the present teachings, for example, but not limited by, various embodiments of fluidic traps of the present teachings, can have a constrained and measurable geometry, allowing for accurate and precise tuning of each fluidic sample volume throughout the on-device liquid handling process.

A microfluidic device, particularly of the lab-on-chip type, for the detection of biological and/or medical targets of interest in biological samples, as well as for the operations of extraction of such targets from native or non-native biological samples, of purification, concentration, and injection in buffer solutions, all adapted to optimize the detection thereof.