Abstract: A microfluidic sorting device and method employing dielectrophoresis (DEP) induced field flow separations are described herein. The microfluidic sorting device has a microchannel and an array of electrodes disposed along the microchannel. The electrodes may be oriented at an angle relative to the microchannel. Non-mammalian samples such as plant samples flow in the microchannel and through the electrode array. Current is passed through the electrodes causing a DEP force to be exerted on the samples. This force may generate a torque that causes one type of sample to rotate and slide along the electrodes, thus separating the samples by type.

Abstract: The present invention is directed to systems and devices that allow for separation of cells based on size and electric properties and for high-throughput cell sorting. The system may comprise a microfluidic platform having a main microfluidic channel and cavity acoustic transducers (CATs). The microfluidic platform may be coupled to an external acoustic source. The system may further comprise a fluid disposed through the main microfluidic channel comprising cells having different sizes and electric properties. The fluid may intersect the CATs to form one or more interfaces. The system may further comprise electrodes underneath the microfluidic platform. The CATs may oscillate the interfaces to produce one or more microstreaming vortices, such that each microstreaming vortex is capable of selectively trapping cells based on size. The set of electrodes may apply an AC to cause the cells to move relative to the set of electrodes based on electric properties.

Abstract: A passive, hydrodynamic technique implemented using a microfluidic device to perform co-encapsulation of samples in droplets and sorting of said droplets is described herein. The hydrodynamic technique utilizes laminar flows and high shear liquid-liquid interfaces at a microfluidic junction to encapsulate samples in the droplets. A sorting mechanism is implemented to separate sample droplets from empty droplets. This technique can achieve a one-one-one encapsulation efficiency of about 80% and can significantly improve the droplet sequencing and related applications in single cell genomics and proteomics.

Abstract: The present invention features the use of cavity acoustic transducers (CATs) to apply mechanical stimuli on cells. CATs utilize the generated acoustic microstreaming vortices to trap cells and apply tunable shear on them. The present invention may use such a portable, automated, and high throughput device for cell transfection.

Abstract: The present invention features the use of lateral cavity acoustic transducers (LCATs) to apply mechanical stimuli on cells. LCATs utilize the generated acoustic microstreaming vortices to trap cells and apply tunable shear-induced cell deformation on them. The present invention may use such a portable, automated, and high throughput device for shear-induced cell transfection.

Abstract: A passive, hydrodynamic technique implemented using a microfluidic device to perform co-encapsulation of samples in droplets and sorting of said droplets is described herein. The hydrodynamic technique utilizes laminar flows and high shear liquid-liquid interfaces at a microfluidic junction to encapsulate samples in the droplets. A sorting mechanism is implemented to separate sample droplets from empty droplets. This technique can achieve a one-one-one encapsulation efficiency of about 80% and can significantly improve the droplet sequencing and related applications in single cell genomics and proteomics.

Abstract: The present invention features the use of lateral cavity acoustic transducers (LCATs) to apply mechanical stimuli on cells. LCATs utilize the generated acoustic microstreaming vortices to trap cells and apply tunable shear-induced cell deformation on them. The present invention may use such a portable, automated, and high throughput device for shear-induced cell transfection.