A single junction sorter for a microfluidic particle sorter, the single-junction sorter comprising: an input channel, configured to receive a fluid containing particles; an output sort channel and an output waste channel, each connected to the input channel for receiving the fluid therefrom; a bubble generator, operable to selectively displace the fluid around a particle to be sorted and thereby to create a transient flow of the fluid in the input channel; and a vortex element, configured to cause a vortex in the transient flow in order to direct the particle to be sorted into the output sort channel.

A flow path device includes a first portion, and a second portion. The first portion includes a resin first body and a first reinforcement. In the first body, a first connector connects a first outer portion and a first joint having a groove pattern defining a first flow path.

The first reinforcement is between and bonded to the first outer portion and the first joint, and includes first protrusions protruding from the first body and including two specific-shaped portions. The second portion includes a resin second body and a second reinforcement. In the second body, a second connector connects a second outer portion and a second joint, and through-holes connect to the first flow path. The second reinforcement is between and bonded to the second outer portion and the second joint, and includes second protrusions protruding from the second body and including two specific-shaped portions.

To provide a microchip that is easily handled.

Provided is a microchip having a plate shape and including: a sample liquid inlet into which a sample liquid is introduced; a main flow path through which the sample liquid introduced from the sample liquid inlet flows; and a sorting flow path into which a target sample is sorted from the sample liquid, in which the sample liquid inlet and a terminal end of the sorting flow path are formed on a same side surface. Furthermore, a sample sorting kit including the microchip is also provided. Moreover, a microparticle sorting device on which the microchip is mounted is also provided.

The present disclosure relates to a microfluidic substrate, a microfluidic device and a driving method thereof. The microfluidic substrate includes a first area, the first area includes a first module for generating droplets, the first module includes a first electrode pair and a second electrode pair, and the first electrode pair and the second electrode pair are arranged in a crisscross pattern. The first electrode pair includes a first electrode and a second electrode, and the second electrode pair includes a third electrode and a fourth electrode.

Cell separation systems, and methods for separating cells from microcarriers, and harvesting the separated cells, are provided, wherein the system comprises a cell separation device, a cell settling device, and a cell screening device.

A method for separating cells in a biofluid includes pretreating the biofluid by introducing a predetermined amount of a cocktail of antibodies, flowing the pretreated biofluid through a microfluidic separation channel, and applying acoustic energy to the pretreated biofluid within the microfluidic separation channel. A system for microfluidic cell separation, capable of separating target cells from non-target cells in a biofluid includes at least one microfluidic separation channel, a source of biofluid, a source of an additive including the cocktail of antibodies, and at least one acoustic transducer coupled to the microfluidic separation channel. A kit for microfluidic cell separation is also disclosed. A method of facilitating separation of cells is also disclosed.

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.

A method for separating and enriching sperm from a tissue sample comprises: obtaining a microfluidic separating system having an inlet end and an outlet end, and a membrane filter (e.g., hollow fiber membrane filter) fluidly connected to the outlet end; separating the tissue sample via the microfluidic separating system into a debris fluid volume and a sperm fluid volume; and enriching the sperm fluid volume by removing excess media via the membrane filter. A two-stage tissue sample separation system comprising: a microchannel structure defining a separation fluid channel to form a separation stage; an inlet end of the microchannel structure; an outlet end of the microchannel structure; and a membrane filter fluidly connected to the outlet end for removal of at least a portion of excess media in the tissue sample.

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.

The present invention provides a magnetic sorting microfluidic chip, including a substrate, a chip model material layer, a micro-channel unit and a magnetic sorting unit, where the chip model material layer is disposed on the substrate, and the micro-channel unit and the magnetic sorting unit are both disposed in the chip model material layer; the micro-channel unit includes a sorting channel and magnetic pole channels; the sorting channel is provided with a plurality of sorting channel inlets and a plurality of sorting channel outlets; and the magnetic sorting unit includes permanent magnets, high-permeability alloys, and magnetic pole arrays disposed in the magnetic pole channels, where the high-permeability alloys are configured to conduct magnetic fields of the permanent magnets to the magnetic pole arrays, so that the magnetic pole arrays generate magnetic fields having opposite polarities on left and right positions of the sorting channel.