A microfluidic sample processing device, capable of automatically processing a microfluidic sample, comprises: a tray apparatus, for accommodating a reagent and a chip clamp for mounting a microfluidic chip; a mechanical arm, having a connecting head for connecting the chip clamp, a gas flow channel for communicating with an inner cavity of the chip clamp being arranged in the connecting head; a negative pressure suction apparatus, for providing negative pressure to the gas flow channel of the connecting head; a lifting apparatus, for driving the connecting head to rise and fall; and a translation apparatus, for driving the connecting head to move to above the chip clamp or above the reagent; wherein, the tray apparatus is positioned below the mechanical arm, and the mechanical arm is arranged on the translation apparatus and is connected to the lifting apparatus.

This disclosure relates to apparatus and methods for molecular diagnostics. Certain embodiments include a piston cycled from a first position proximal to a first end of a housing, to a second position proximal to a second end of the housing, and back to the first position proximal to the first end of the housing. In some embodiments, the present disclosure relates to devices, methods, and systems for molecular diagnostics that do not comprise a piston.

The present invention relates to a sample container having a new structure to effectively transfer a sample. A sample container according to the present invention includes: a container main body 10 that is formed in a cup shape having an open top surface, and a coupling hole 11 opened in a vertical direction is formed on one side of the container main body 10; a closed and sealed cover 20 that is coupled to an upper end of the container main body 10 to close and seal the container main body 10; and a detachably coupled collection tube 30 that is formed in the shape of a tube that extends in a vertical direction while having an open top surface, and is detachably coupled to the coupling hole 11, wherein a slope 12 that is inclined downward to the inside of the container main body 10 is formed on one side of an external circumferential surface of the container main body 10, wherein a recess portion 13 of which a lower end is open, and the recess portion 13 is formed on one side of the external circumferential surface of the container main body 10, and wherein the coupling hole 11 is formed to penetrate top and bottom surfaces of the recess portion 13, and the coupling hole 11 is formed on the top surface of the recess portion 13, accordingly, there is a merit that, after containing urine in the container main body 10 and combining the closed and sealed cover 20, the container main body 10 can be tilted to easily transfer urine to the collection tube 30 and the urine can be prevented from outflowing and contaminating the surrounding area, being contaminated, or being mistakenly switched.

A system for preparing a thrombin serum that can include a containment device, a cage received within the containment device, a cap attachable to the containment device, an inlet port configured to introduce a non-anti-coagulated autologous blood fluid into the containment device, and an outlet port. An activator, such as glass beads, can be present within the containment device.

A microfluidic chip is provided for self-sorting highly motile, morphologically normal sperm cell with high DNA integrity from a fresh semen sample. The sperm self-sorting microfluidic chip has one or more inlet chambers, and sperm collection outlet chamber(s), and the middle of the channel features various micro-fabricated structures in different geometrical shapes and orientations, with varying periodicities and patterns, such as an array of micro-fabricated pillars that facilitate the transport of the active and healthy sperm into the outlet chamber.

The present invention relates to a flow-through device comprising at least one separation column wherein a first packing component, which comprises particles of alumina and/or silica, and a second packing component, which comprises a powder of one or more hygroscopic salts are provided. The two packing components may be blended or layered in the device, which may comprise a single tube or a plurality of tubes arranged in a plate format, such as the wells of a multiwall plate or tubes in a rack. In addition, the invention relates to a method for removing one or more matrix components, such as pigments, from a biological sample, by passing said sample across a first packing component, which comprises particles of alumina and/or silica, and a second packing component, which comprises a powder of one or more hygroscopic salts.

A container carrier for carrying a sample container along a track is presented. The container carrier comprises a holding portion for receiving and holding a sample container and a base portion. A radio frequency identification (RFID) tag containing identifying information is provided with an antenna for wireless communication of the RFID tag with a reader device of the diagnostics system to read the identifying information. The RFID tag is on the holding portion. An arrangement for a diagnostics system is provided comprising container carriers and a track with a transport mechanism for moving the container carriers along a transportation lane. The transport mechanism defines a transport plane along which the container carriers move. A reader device reads the identifying information from the RFID tags. The reader device comprising a reader antenna above the transport plane to generate and emit a reader field for wireless communication with the RFID tag's antenna.

The invention relates to a method and a system for providing fluids, comprising two components, wherein a first component is a container with at least one first reservoir for taking up a fluid and a second reservoir for ventilation of the system, wherein said first and second reservoir are sealed with a seal, and a second component which is a dock for taking up the container, wherein the dock comprises an inner bottom surface comprising first formations for fluid piercing of the container's at least one first reservoir for taking up a fluid and second formations for piercing of the container's second reservoir for ventilation, and wherein said inner bottom surface is a drain plate comprising a drain, wherein the container has fins on its outer edge which engage into two parallel arranged recesses at the inner side surface of the dock for fixing the container within the dock in a first position when the fins of the container engage in a first recess which is a storage snap fit or a second position when the fins of the container engage in second recess at the inner side surface which is a retain snap fit.

A test strip container includes: an accommodating member in which a test strip is accommodated; a moving member moving the test strip therein; a door member opening and closing at a side surface of the accommodating member to discharge the test strip out of the accommodating member, and cutting the interior and the exterior of the accommodating member off from each other when closed; a door accommodating portion covering the door member, in which the door member can open and close; and a discharge opening cutting the interior and an exterior of the door accommodating portion off from each other when closed, and is provided at the door accommodating portion so as to open and close to discharge the test strip to the exterior of the door accommodating portion, the discharge opening being able to open when the accommodating member is closed by the door member.

Separation of the cellular components of whole blood, or other biological fluid, from plasma or serum can be achieved for assay analysis. A device for facilitating separation can include, for example, a capillary tube that accurately draws target blood volume, a pad that chemically interacts with red-blood cells, such that the red blood cells become chemically and/or physically trapped within pad material, a mechanism for plasma recovery from the pad upon diffusion or active mixing, and a dropper tip that facilitates dispensing the mixture onto a test device. The treatment of the cellular components can be performed prior to contact with a buffer solution, so release of the cellular components into the buffer solution is reduced or prevented. Additional filtration can be provided to filter any remaining cellular components in the mixture.