In situ-generated microfluidic capture structures incorporating a solidified polymer network, methods of preparation and use, compositions and kits therefor are described. Microfluidic capture structures may be advantageously used for assays performed within the microfluidic environment, providing flexibility in assaying micro-objects such as biological cells. Assay reagents and analytes may be incorporated within the microfluidic capture structures.

Devices, techniques, and processes are disclosed that use electrical impedance to detect of the presence and contents of droplets including cells, nucleic acids, proteins, or solute concentrations in an array of retrievable, trackable, trapped droplets in a fluidic system. Electrodes may be positioned underneath individual droplet traps in a microchannel to assay droplet contents and/or actuating droplets for the release of the droplets from corresponding traps. The disclosed technology may be used for detection of the results of solvent extraction processes including time-dependent quantification of metal ion concentration in the aqueous and organic phases, for wastewater treatment, heavy metal detection, pharmaceutical industry, and/or biotechnology, or for environmental monitoring of wastewater for toxic metal, monitoring of biological cell viability and proliferation, monitoring of extraction processes used in heavy metal mining, monitoring of extraction processes used in nuclear fuel processing, monitoring kinetics of enzyme processes, and/or assessing pharmacodynamics and drug efficacy.

The present technology relates to improved device and methods of use of insulator-based dielectrophoresis. This device provides a multi-length scale element that provides enhanced resolution and separation. The device provides improved particle streamlines, trapping efficiency, and induces laterally similar environments. Also provided are methods of using the device.

Disclosed herein are systems and methods capable of identifying, tracking, and sorting particles flowing in a channel, for example, a microfluidic channel having a fluid medium. The channel and the fluid medium can have a similar refractive index such that they appear translucent or transparent when illuminated by electromagnetic radiation. The particles can have a refractive index substantially different from that of the channel and the medium, such that the particles interfere with the electromagnetic radiation. A sensor can be disposed adjacent to the channel to record the electromagnetic radiation. The sensor can be used for identifying, tracking, and sorting the particles.

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 microfluidic device can comprise at least one swept region that is fluidically connected to unswept regions. The fluidic connections between the swept region and the unswept regions can enable diffusion but substantially no flow of media between the swept region and the unswept regions. The capability of biological micro-objects to produce an analyte of interest can be assayed in such a microfluidic device. Biological micro-objects in sample material loaded into a microfluidic device can be selected for particular characteristics and disposed into unswept regions. The sample material can then be flowed out of the swept region and an assay material flowed into the swept region. Flows of medium in the swept region do not substantially affect the biological micro-objects in the unswept regions, but any analyte of interest produced by a biological micro-object can diffuse from an unswept region into the swept region, where the analyte can react with the assay material to produce a localized detectable reaction. Any such detected reactions can be analyzed to determine which, if any, of the biological micro-objects are producers of the analyte of interest.

A microfluidic apparatus for forming one or more droplets of an aqueous fluid suspended in a non-aqueous fluid is described. The microfluidic apparatus includes a first microfluidic channel configured for flowing an aqueous fluid through the first microfluidic channel and a second microfluidic channel fluidically connected to the first microfluidic channel and adapted to flow a non-aqueous fluid through the second microfluidic channel into the first microfluidic channel. A microfluidic reservoir fluidically connected to the first microfluidic channel and configured to receive a plurality of droplets of the first aqueous fluid. The microfluidic apparatus further includes a first electrode and a second electrode positioned such that application of voltage to the first electrode moves one or more droplets of the aqueous fluid in a first direction and application of voltage to the second electrode moves one or more droplets of the aqueous fluid in a second direction.

This disclosure provides photonic integrated chip that has an optical waveguide located on a photonic circuit substrate that includes a photonic circuit that is optically coupled to the waveguide. A microfluidic channel is in a silicon substrate and is attached to the photonic circuit substrate. The microfluidic channel is positioned over the optical waveguide such that its side surfaces and an outermost surface extend into the microfluidic channel. The microfluidic channel extends along a length of the optical waveguide, and nanoparticles are located on or adjacent the optical waveguide located within the microfluidic channel.

The present invention includes methods, devices and systems for isolating, identifying, analyzing, and quantifying biological materials from fluid samples. In various aspects, the methods, devices and systems may allow for a rapid procedure that requires a minimal amount of material and/or results in high purity biological materials from complex fluids such as blood, serum, or plasma.

A microfluidic device comprising one or more fluidic microchannels and one or more arrays of cell assay units is disclosed. Each cell assay unit in turn comprises at one bipolar electrode, micropocket, reaction chamber, and leak channel. In some embodiments, the cell assay unit further comprises two or more split BPEs inside the reaction chamber. The disclosed microfluidic device can be used to separate cells, especially rare cells, from its biological matrix and then analyze the isolated cell inside the reaction chamber. The disclosed device can isolate and analyze cells in a high-throughput fashion and without any modification or labelling to the cells. Cells isolated using the disclosed devices does not lose their vitality.