Methods and systems are provided for a microfluidic cartridge including a high performance actuator useful for analyte detection, labeling and analysis. Microfluidic processing systems are to carry out chemical or biochemical reactions, or sequences of reactions, with small volumes (typically between 1 microliter and 10 milliliters) of reactants and products. A microfluidic processing system can comprise a network of tubes interfaced with discrete components such as valves and sensors, or an integrated device made of plastic, glass, metal, or other materials, or a combination of materials, with components such as valves and sensors built into the device and connected by flow passageways formed in the material.

A microfabricated valve with no moving parts. In one embodiment, the valve includes a reservoir of a liquid that is in fluid communication with an outlet channel having a throat that is less than 100 microns wide. Preferably, the channel is an elongated slit. The configuration of channel is adapted and configured such that surface tension of the liquid prevents flow out of the channel. A heater increases the temperature of the meniscus of the fluid, until a portion of the fluid is ejected from the channel. The ejection of the fluid creates both a thrusting effect and a cooling effect.

Embodiments of the invention provide a microfluidic chip having microfluidic structures formed on a surface. The structures form an input channel, an output channel, auxiliary channels, and a hydraulic resistor structure connecting the input channel to the output channel via the auxiliary channels. The resistor structure includes N flow resistor portions (N2), which are connected to the auxiliary channels. The chip further includes at least N1 actuatable valves, which are arranged in respective ones of the auxiliary channels. The actuation state of the valves can determine the effective hydraulic resistance of the resistor structure. The valves can be electrogates, each including a liquid-pinning trench arranged in a respective one of the auxiliary channels that define a flow path for a liquid introduced therein, so as to form an opening that extends across said flow path. Each electrogate can further include an electrode extending across the flow path.

A curtain airbag device mounting structure includes: a first pillar forming a part of a front pillar and extends substantially along a vehicle height direction; a second pillar forming another part of the front pillar, the second pillar being disposed on a rear side of a vehicle relative to the first pillar at a predetermined distance from the first pillar and extending substantially along the vehicle height direction; a transparent member bridged between the first pillar and the second pillar; and a curtain airbag device including a curtain airbag stored along a roof side rail and the second pillar, the curtain airbag being configured to inflate and deploy in a curtain-like fashion over a side portion of a cabin of the vehicle in case of a collision of the vehicle.

A self-driven microfluidic chip for rapid influenza A detection is provided. The chip includes: a substrate, a hydrophobic layer, a hydrophilic film layer, and a channel structure layer laminated sequentially. The structure of the channel structure layer includes a plurality of channels, a plurality of valves and reaction chambers in the channels, and a plurality of openings, wherein the hydrophilic film layer includes a pattern corresponding to the structure of the channel structure layer, and forms a disconnected area corresponding to the location of the valves to make the valves hydrophobic; the channel structure layer is formed of a flexible material, and heights of the valves are higher than those of the channels in a thickness direction of the channel structure layer in order to control liquid flow by pressing the valves.

A method of extracting assay fluid from an EWOD device, the EWOD device comprising two opposing substrates defining a fluid space there between and an aperture for extraction of fluid from the fluid space. The method comprises providing, in the fluid space of the EWOD device, a droplet of assay fluid adjacent to the aperture such that the droplet blocks extraction, via the aperture, of filler fluid contained in the fluid space of the EWOD device, and extracting, via the aperture, at least some of the assay fluid of the droplet from the fluid space. The method comprises, during the extracting, controlling the assay fluid droplet by electrowetting to maintain the blocking of extraction of filler fluid. By controlling the position of the unextracted portion of the assay fluid droplet relative to the aperture during the extraction process, the unextracted portion of the assay fluid droplet continues to block extraction of filler fluid. This makes it much less likely for unwanted extraction of filler fluid to occur.

A system for testing for an analyte includes a test strip. The test strip includes a first flow path. The test strip further includes a heating element in communication with a heating area of the first flow path, for heating a sample in the first flow path. The test strip further includes an e-gate, the e-gate in the first flow path, the e-gate separating the heating area from a detection area of the first flow path.

A microfluidic analysis device and manufacturing method are provided. The microfluidic analysis device includes a capillary substrate, a cover substrate adjacent to a cover side of the capillary substrate and/or a bottom substrate adjacent to a bottom side of the capillary substrate, a capillary structure with at least one capillary, forming a hollow channel, in the interior of the capillary substrate and/or at the interface of the capillary substrate with the cover substrate and/or at the interface of the capillary substrate with the bottom substrate and also a fluid-conducting arrangement for conducting a fluid through the capillary structure. The fluid-conducting arrangement may be designed for compartmenting the fluid by way of controlled pressure pulses. A linear sensor element, which extends toward a capillary of the capillary structure and/or away from it and/or along the capillary, and a fluid contact end of which and at least an adjacent part of its feed lie in an identical plane to the capillary, may be integrated in the microfluidic analysis device, the element finishing with its fluid contact end flush against a side wall of the capillary or extending into the hollow channel thereof.

A microfluidic valve may include a first portion of a liquid conduit to contain a gas, a second portion of a liquid conduit to contain a liquid, and a constriction between the first portion and the second portion and across which a capillary meniscus is to form between the gas and the liquid. The microfluidic valve may further include a drop jetting device within the second portion to open the valve by breaking the capillary meniscus across the constriction.

Systems and methods for fabricating 3D soft microstructures. The system comprises injecting a pressurized, curable liquid into certain structural layers induces folding and allows the 2D structures to reconfigure into a 3D form In addition to the injection of a curable liquid that permanently reconfigures the structure of the system, in an embodiment this method also allows for the injection of other liquids into certain actuator layers that enable motion in certain portions of the system Furthermore, the system allows for handling of colored fluids that are passed to visualization layers. The method of creating such a system depends on taking advantage of laser machining of the individual layers to influence the behavior of how different portions bend and move.