The invention relates to a method for setting a cell concentration and/or a particle concentration in a dispensing device by means of which a liquid sample can be discharged, wherein the cell concentration and/or the particle concentration is ascertained in one region of the dispensing device, and the cell concentration and/or particle concentration that has been ascertained is compared with a target value, and a force exerted on one cell and/or one particle is adjusted based on the result of the comparison.

The present invention relates to droplet-based surface modification and washing. According to one embodiment, a method of splitting a droplet is provided, the method including providing a droplet microactuator including a droplet including one or more beads and immobilizing at least one of the one or more beads. The method further includes conducting one or more droplet operations to divide the droplet to yield a set of droplets including a droplet including the one or more immobilized beads and a droplet substantially lacking the one or more immobilized beads.

Disclosed herein include methods, compositions, and kits suitable for use in sorting a population of cells. In some embodiments, the method comprises flowing a fluid sample comprising a population of cells through a microfluidic channel. The population of cells can be configured to express gas vesicles (GVs) in a context-dependent manner. The expression of GVs within a cell can increase the compressibility (β) and reduce the density (ρ) of said cell, thereby modulating the acoustic contrast (Φ) of said cell relative to the fluid in the microfluidic channel. The method can comprise applying ultrasound to the microfluidic channel. Applying ultrasound can generate acoustic standing wave(s) in the microfluidic channel, thereby positioning pressure antinode(s) in the microfluidic channel.

Exemplary embodiments of the present disclosure provide for two-stage microfluidic devices using surface acoustic waves, methods of use thereof, methods of making, methods of focusing and separating particles, and the like.

A chemical, biochemical or biological analysis system and method including: a surface acoustic wave (SAW) actuator (6) including a piezoelectric substrate (9) and at least one interdigital electrode (17) located on a working surface (11) of the piezoelectric substrate (9), the SAW actuator generating travelling SAWs in the working surface when an electrical signal is applied to the interdigital electrode; at least one reaction chamber (19) located on the working surface of the piezoelectric substrate; a light detector (16) for detecting luminescent, fluorescent or phosphorescent emissions within the reaction chamber; a reagent flow line (29) for providing a flow of reagent through the reaction chamber; a test sample supply line (29) for supplying a test sample to the reaction chamber; wherein the SAW actuator can generate travelling SAWs within the working surface to thereby induce chaotic micromixing, convective transport, concentration or combinations thereof of the test sample and the reagent contained within the reaction chamber.

The present invention generally relates to the manipulation of fluids using acoustic waves such as surface acoustic waves. In some aspects, one fluid may be introduced into another fluid via application of suitable acoustic waves. For example, a fluid may be added or injected into another fluid by applying acoustic waves where, in the absence of the acoustic waves, the fluid cannot be added or injected, e.g., due to the interface or surface tension between the fluids. Thus, for example, a fluid may be injected into a droplet of another fluid. Other embodiments of the invention are generally directed to systems and methods for making or using such systems, kits involving such systems, or the like.

A sensor is provided for detecting and characterizing particles in a fluid. The sensor has a microfluidic channel for receiving the fluid sample, an acoustic transducer module configured to generate a standing wave for concentrating the particles in a region of the microfluidic channel; an optical detection module configured to detect optical signals scattered by the particles upon illuminating the region of the fluid sample with a light source; and a data processing module configured to characterize the particles of the fluid sample based on the optical signals using a classifier.

A microfluidic device and method is provided for concentrating particles in a fluid sample. The microfluidic device has a chamber, wherein the chamber has a filtering unit defining a first compartment and a second compartment, the first compartment being in fluid communication with the second compartment and being for receiving a fluid sample containing particles, the filtering unit being configured to selectively retain particles of the fluid sample based on a size of the particles, at a sub-region of the first compartment as the fluid sample flows from the first compartment to the second compartment; and an acoustic transducer configured to generate acoustic waves in the sub-region to disperse the particles.

A method of treating a biological sample, preferably a sample of blood or bodily fluids likely to contain one or more species of interest, and including a step of decomplexification by acoustophoresis (as well as associated systems, devices, substrates and connection devices).

A microscope slide holder comprising a slide support member and at least one acoustic source for introducing acoustic waves to a microscope slide in communication with the slide support member such that one or more fluids present on the surface of the microscope slide are contactlessly mixed.