An apparatus and method for isolating bacterial particles in a sample using a container with material in temporary fluid blocking position to lower orifice in the container, a separation medium having an electrical conductivity lower than and physical density greater than that of the sample above the material that supports a sample concentrate after passing through the separation medium when exposed to centrifugal force, a heating element for liquefying the material to permit flow into a chamber past an electrode array that attracts and holds subject particles. The system allows rapid detection and isolation of particles from samples from animal, human, environmental sites, a bio-industrial reactor or a food or beverage production facility requiring relatively small volumes, short incubation times resulting in structurally intact particles for further analysis. Testing may be completed in a single unit that requires decreased technician manipulation, fewer steps and a decrease in cross-contamination.

A valve system for driving fluid and a method for using the same are provided. The valve system includes a fluid unit far away from the rotation center, a fluid unit close to the rotation center, a fluid transferring unit and a gas path pipeline for communicating the fluid unit close to the rotation center with the fluid unit far away from the rotation center. A rotation radius of a fluid outlet of the fluid unit far away from the rotation center is greater than that of a fluid inlet of the fluid unit close to the rotation center. The fluid outlet of the fluid unit far away from the rotation center is located at an end thereof away from the rotation center, and the fluid inlet of the fluid unit close to the rotation center is located at an end thereof close to the rotation center.

A sample carrier is used in a rotation-based method for reproducing or detecting DNA. The sample carrier has a disc-like main part and a plurality of cavities formed in the main part, in which cavities, a sample fluid at least potentially containing DNA is received. A disc side of the main part forms a heat entry side and the flat side facing away therefrom forms a heat discharge side. The cavity or one of a plurality of cavities, as applicable, is formed by an annular channel having a first and a second channel portion, which are fluidically connected at both longitudinal ends by a connection portion in each case. The first channel portion is arranged offset relative to the second channel portion in the thickness direction of the main part.

A cell washer is disclosed. The cell washer includes a vessel configured to hold cells. The vessel includes an elongated body including an opening, an inner surface, and a pocket defined by a first inner surface portion of the inner surface disposed between and radially outward relative to a second inner surface portion and a third inner surface portion of the inner surface, and a cavity. The vessel also includes an actuating device capable of causing the vessel to spin about an axis.

The invention provides a viscometer and an operation method thereof. The viscometer comprises a disk and at least one microfluidic structure. The microfluidic structure is embedded in the disk and has a first chamber which is connected to a second chamber. The second chamber is provided with an annular chamber along the circumferential direction of the disk and comprises at least one indicator. Overall, the present viscometer and its operation method do utilize the oscillation amplitude of pendulum motion of the indicator to calculate a viscosity value (cP) of a sample which has already existed in the second chamber.

There is provided a microfluidic device comprising a first region configured to hold target cells, e.g., tumor cells, a second region configured to hold effector cells, e.g., immune cells, and an array of microstructures disposed between the first and second regions, wherein the first region is in fluid communication with the second region, and wherein the array of microstructures is configured to selectively allow movement of immune cells, from the second region to an interaction zone that is at least partially disposed within the first region, for interaction with tumor cells in the interaction zone. The array of microstructures can be an array of micropillars. Also provided is a chip comprising a plurality of the device and a method of studying interactions of a first cell type with a second cell type.

The microfluidic chip according to an embodiment of the present invention may include a plate, a bridge channel formed in intaglio on one side of the plate, an inlet formed through the plate to communicate with one end of the bridge channel, an outlet formed through the plate to communicate with the other end of the bridge channel, and at least one well extending in an outward direction of the plate from the bridge channel to provide a space, wherein the bridge channel may be in the form of a curved line, a bent line, an arc, a circle, a spiral, or a polygon.

The present disclosure describes a disc-like apparatus and method of its use allowing for the one-step concentration and separation of therapeutic factors found in mammalian body fluid.

A nucleic acid sequencing system may include a substrate coupled to a rotating disk. The substrate may include a plurality of nucleic acid samples. A detection system, including for example an objective and a camera, may detect sequencing events on the substrate while the substrate is rotated relative to the detection system around a rotational axis of the substrate, perpendicular to a surface of the substrate, by the actuation system.

A method herein to isolate exosomes includes providing a microfluidic device having a spiral-shaped channel in fluid communication with two inlet ports and at least two outlet ports. One of the two inlet ports is proximal to an inner wall of the spiral-shaped channel and the other is proximal to an outer wall thereof. At least one of the outlet ports is in fluid communication with a container for storing isolated exosomes. A blood sample and sheath fluid are introduced into the inlet ports proximal to the outer and inner walls, respectively, to form a diluted sample in the spiral-shaped channel and driven through for exosomes recovery in the container. The spiral-shaped channel in fluid communication with a first outlet port includes a first outlet channel connecting the spiral-shaped channel to the first outlet port and is longer than other outlet channels respectively connecting the spiral-shaped channel to the other outlet ports. A method of identifying diabetes mellitus is also disclosed herein.