Embodiments in accordance with the present invention relate to methods and apparatuses for concentrating and isolating Circulating Tumor Cells (CTCs) from body fluids. One embodiment of the present invention includes a micro-fabricated or nano-fabricated device having channels configured for separating and excluding. Embodiments in accordance with the present invention utilize features that reduce the hydrodynamic pressure experienced by the cells during the separation, isolation and concentration processes, and therefore reduce the likelihood of cell lysis or other damage to the cells.

This invention relates to compositions of matter, methods, modules and instruments for automated mammalian cell growth and mammalian cell transduction followed by nucleic acid-guided nuclease editing in live mammalian cells.

The invention relates to a microfluidic system based on active control of flow resistance and balancing pressures in microfluidic channels and an improved method for enhancing reactions with magnetic beads used in disposable microfluidic devices and cartridges for use in, but not limited to, in-vitro diagnostics. The microfluidic system and device of the invention does not utilize mechanical moving parts to control the fluid flow and has no external fluidic connection to the instrument or fluidics controller. The microfluidic system and device combines magnetic control over the movement of magnetic detection beads with electric field and convective enhancement of the movement of analytes and/or or reagentss surrounding the magnetic detection beads, thereby enabling movement of magnetic beads and analytes in the same direction or in different directions. The present invention thereby provides significantly enhanced interactions between analytes and/or reagents with the magnetic beads, which yields higher sensitivity for detection.

A detection device for detecting a marker in a liquid, preferably a fuel, comprising:

a reaction chamber 5, provided with a de-dopable conductive polymer 6 building a path between two conductive pads 10 connected to a resistivity measurement device, wherein the de-dopable conductive polymer 6 is able to be de-doped by a chemical reaction with the marker, changing its resistivity.

During droplet operations in a droplet actuator, bubbles often form in the filler fluid in the droplet operations gap and interrupt droplet operations. The present invention provides methods and systems for performing droplet operations on a droplet in a droplet actuator comprising maintaining substantially consistent contact between the droplet and an electrical ground while conducting multiple droplet operations on the droplet in the droplet operations gap and/or reducing the accumulation of electrical charges in the droplet operations gap during multiple droplet operations. The methods and systems reduce or eliminate bubble formation in the filler fluid of the droplet operations gap, thereby permitting completion of multiple droplet operations without interruption by bubble formation in the filler fluid in the droplet operations gap.

This invention provides methods and compositions, e.g., to reduce interference from non-specific binding sample constituents in a migration shift assay. Interference due to non-specific binding of sample constituents to an affinity substance (e.g., an affinity molecule or a conjugate of an affinity molecule and a charged carrier molecule) is prevented by, e.g., binding the constituents to charged polymers such as heparin sulfate. The present invention also provides methods to concentrate an analyte of interest with high concentration and to detect the analyte with high sensitivity, and further to optimize the reaction conditions for easily concentrating the analyte. Such objects of the present invention are attained, for example, by concentrating a complex of the analyte and a conjugate which is formed by contacting the analyte in a sample with an affinity molecule bound to a charged carrier molecule such as DNA.

The present invention generally relates to systems and methods for the control of fluids and, in some cases, to systems and methods for flowing a fluid into and/or out of other fluids. As examples, fluid may be injected into a droplet contained within a fluidic channel, or a fluid may be injected into a fluidic channel to create a droplet. In some embodiments, electrodes may be used to apply an electric field to one or more fluidic channels, e.g., proximate an intersection of at least two fluidic channels. For instance, a first fluid may be urged into and/or out of a second fluid, facilitated by the electric field. The electric field, in some cases, may disrupt an interface between a first fluid and at least one other fluid. Properties such as the volume, flow rate, etc. of a first fluid being urged into and/or out of a second fluid can be controlled by controlling various properties of the fluid and/or a fluidic droplet, for example curvature of the fluidic droplet, and/or controlling the applied electric field.

The present invention relates to a method of sorting particles in a stream of carrier fluid, the method comprising: introducing a stream of carrier fluid containing a mixture of particles into a stream of sheath fluid flowing within a flow channel so as to focus the carrier fluid into a core stream; detecting a particle of interest within the core stream of carrier fluid at a point of detection within the flow channel; applying a potential difference between a first electrode and one or more additional electrodes so as to generate a divergent electric field localised around a tip of the first electrode, wherein the tip of the first electrode is positioned inside of the flow channel or adjacent to the flow channel in a position in which the divergent electric field is experienced by the sheath fluid and carrier fluid within the flow channel, and subsequently terminating application of the potential difference, wherein the potential difference is applied in response to the detection of a particle of interest, the applied potential difference being sufficient to generate a centripetal force on a volume of carrier fluid within the divergent electric field, said volume of carrier fluid containing the particle of interest, so as to displace said volume of carrier fluid in a direction having a component orthogonal to the direction of flow, such that the particle of interest is diverted into a desired outlet of the flow channel.

Disclosed is a device for moving a liquid in a substantially loss-free operation, the device made of at least a photothermal film; a pyroelectric crystal over the photothermal film; and a superomniphobic surface over the pyroelectric crystal, wherein the device is configured to move the liquid in the substantially loss-free operation with a beam of light.

A detection chip and a detection system are provided. The detection chip includes a base substrate, a flow channel defining layer, and at least one driving electrode group. The at least driving electrode group is on the base substrate, and the flow channel defining layer is on a side of the at least one driving electrode group away from the base substrate, the flow channel defining laver includes a flow channel structure, and the flow channel structure is configured to accommodate liquid; and each of the at least one driving electrode group includes a plurality of driving electrodes, and the plurality of driving electrodes are configured to contact the liquid and drive the liquid to move within the flow channel structure.