Methods are provided for separating magnetically responsive beads from a droplet in a droplet actuator. Droplet operations electrodes and a magnet are arranged in a droplet actuator to manipulate a bead-containing droplet and position it relative to a magnetic field region that attracts the magnetically responsive beads. The droplet operations electrodes are operated to control the droplet shape and transport it away from the magnetic field region to form a concentration of beads in the droplet. The continued transport of the droplet away from the magnetic field causes the concentration of beads to break away from the droplet to yield a small, concentrated bead-containing droplet immobilized by the magnet.

An acoustic liquid transfer system comprises: a processor; a source holding component configured to hold a source microplate; a destination holding component configured to hold a destination microplate; an acoustic transducer configured to cause liquid to transfer between the source and destination microplates; and a controller configured to direct movements, according to an ordered picklist, of one or more of the: source holding component, destination holding component, and acoustic transducer. The processor is configured to access an initial picklist of a plurality of source/destination pairs; obtain a current source/destination pair on the ordered picklist being created, calculate a plurality of movement metrics between the current source/destination pair and at least some of the plurality of source/destination pairs on the initial picklist but not yet on the ordered picklist, select a next source/destination pair with reference to the movement metrics: and add the next source/destination pair to the ordered picklist.

A fluidic device includes a channel in which a fluid flows, and an ultrasonic element generating standing wave in the fluid within the channel by applying ultrasonic wave to the fluid, wherein the channel has a first portion formed using a resin material having a first reflectance of ultrasonic wave propagating in the fluid less than a predetermined value and a second portion having a second reflectance of ultrasonic wave propagating in the fluid equal to or more than the predetermined value, and the second portion is placed on two different surfaces along a flow direction of the fluid within the channel.

Systems and methods for cleansing blood are disclosed herein. The methods include acoustically separating target particles from elements of whole blood. The whole blood and capture particles are flowed through a microfluidic separation channel formed in a thermoplastic. At least one bulk acoustic transducer is attached to the microfluidic separation channel. A standing acoustic wave, imparted on the channel and its contents by the bulk acoustic transducer, drives the formed elements of the blood and target particles to specific aggregation axes.

A system and method are provided for loading a sample into an analytical instrument using acoustic droplet ejection (“ADE”) in combination with a continuous flow sampling probe. An acoustic droplet ejector is used to eject small droplets of a fluid sample containing an analyte into the sampling tip of a continuous flow sampling probe, where the acoustically ejected droplet combines with a continuous, circulating flow stream of solvent within the flow probe. Fluid circulation within the probe transports the sample through a sample transport capillary to an outlet that directs the analyte away from the probe to an analytical instrument, e.g., a device that detects the presence, concentration quantity, and/or identity of the analyte. When the analytical instrument is a mass spectrometer or other type of device requiring the analyte to be in ionized form, the exiting droplets pass through an ionization region, e.g., an electrospray ion source, prior to entering the mass spectrometer or other analytical instrument. The method employs active flow control and enables real-time kinetic measurements.

A system and method for diagnosing infectious disease using integrated surface acoustic wave sensor technology includes an efficient, low-cost integrated surface acoustic wave (SAW) biosensor based system for point-of-care diagnostics. The SAW biosensor, sample receiving portions and interface portions of the system are configured on a disposable cartridge.

A method is provided for manipulating objects in a cavity including a liquid, the method including providing in at least one region of the cavity objects capable of absorbing light in a given wavelength range, forming an aggregate of the objects by submitting them to an acoustic field, and disrupting the aggregate by submitting the aggregate to a light beam emitting at the given wavelength range. Also provided is a device for manipulating objects.

A centrifugal microfluidic technique for heat treating emulsion-divided independent reaction volumes (IRVs) within a centrifugal microfluidic chip, and displacing the emulsion into a monolayer presentation chamber (pc) for imaging. A deep treatment chamber (tc) is provided for the heat treatment, a nozzle having a hydrodynamic radius for forming the IRVs is provided for injecting a sample for the IRVs into the tc filled with a dense immiscible medium. The tc is adjacent a heat controlled element for collectively heat treating the IRVs within the tc, where the IRVs form a 3d packing arrangement. The tc is coupled to a presentation chamber (pc) by an opening through which the IRVs can be selectively displaced without collapsing. The pc is adjacent a window transparent to a wavelength for inspecting the pc.

A microfluidic system can include a substrate comprising an elastic material and defining a microfluidic channel. The substrate can have a first set of dimensions defining a thickness of a wall of the microfluidic channel and a second set of dimensions defining a width of the microfluidic channel. A transducer can be mechanically coupled with the substrate. The transducer can be operated at a predetermined frequency different from a primary thickness resonant frequency of the transducer. A thickness and a width of the transducer can be selected based on the first set of dimensions defining the thickness of the wall of the microfluidic channel and the second set of dimensions defining the width of the microfluidic channel.

A system (100) and a method for detecting fluorescence is disclosed. The system (100) essentially comprises a labelled sample wherein said labelled sample emits an electromagnetic radiation of a defined wavelength when irradiated by a LASER beam of a commensurate wavelength, a source (102) for emitting said LASER beam, oriented as to aim at said labelled sample, a chamber for holding said labelled sample during said LASER irradiation, a reflective layer (108) positioned to reflect said electromagnetic radiation, and a detector (112) positioned to detect and amplify said electromagnetic radiation. The method essentially comprises the steps of providing a labelled sample wherein said labelled sample emits an electromagnetic radiation of a defined wavelength when irradiated by a LASER beam of a commensurate wavelength, providing a source (102) for emitting said LASER beam, oriented as to aim at said labelled sample, providing a chamber for holding said labelled sample during said LASER irradiation, providing a reflective layer (108) positioned to reflect said electromagnetic radiation, providing a detector (112) positioned to detect and amplify said electromagnetic radiation, irradiating said sample with said LASER beam and analyzing said amplified electromagnetic radiation from said detector (112) with a signal processing block (114).