Described herein are systems and methods used for washing needle assemblies with multiple needles.

The present disclosure relates to a portable device for collecting and/or concentrating in situ plankton microbiome, configured for submersion in water. The device herein disclosed is a compact and low-cost autonomous biosampler, with the ability to yield DNA samples for later genomic analysis.

The present invention relates to a method and device for collecting, washing and drying solid particle samples used in collecting the solid particle samples in sample collection work in the fields of industrial production and scientific research, and particularly relates to a method and device for collecting, washing and drying solid particles by pneumatic conveying. A method for collecting, washing and drying solid particles by pneumatic conveying comprises: collecting and conveying a sample mixture containing solid particles into a solid particle collecting and processing device by a pneumatic conveying airflow; then disturbing and diluting the collected sample mixture containing solid particles in the solid particle collecting and processing device by the pneumatic conveying airflow and a washing liquid to filter and wash solid particle samples. The present invention overcomes the problems in the prior art: washing and drying to realize automatic one-stop completion of collection.

A device for handling a sample containing liquid components comprises a housing, a retaining part-unit for holding a storage unit containing the sample, a drive unit for moving the retaining part-unit, and at least one sample-taking body located in the housing. The drive unit has a drive member and a movement-transfer part-unit connected tHereto, and the movement-transfer part-unit has at least one rotation axle. The drive member of the drive unit has a single drive motor, while the movement-transfer part-unit is adjacent to a carrying structure that rotates around the rotation axle(s) of the movement-transfer part-unit. A drive-transfer unit is inserted between the carrying structure and the drive motor, the carrying structure having first and second moving elements which have first and second control bodies, respectively, falling outside of first and second rotation axles, respectively. The first and second moving elements have a periodical, movement-transfer positive coupling link with each other.

Disclosed is a specimen processing method of processing, by using a specimen processing device, a urine specimen contained in a specimen container having an opening. The method includes: sealing, with a seal, the opening of the specimen container containing the urine specimen; aspirating the urine specimen in the specimen container by using an aspiration tube, of the specimen processing device, which has penetrated through the seal; and processing the aspirated urine specimen.

A gripper having a mechanical coupling that can be connected to a pipetting tube, at least one fluid channel extends from the coupling and a negative pressure can be transmitted, the gripper having at least one suction cup that is connected to the coupling through the at least one fluid channel as a result of which the negative pressure can be transmitted from the coupling to the at least one suction cup, and the at least one suction cup in the intended use position of the gripper is aligned such that a rim of a suction cup of the at least one suction cup is aligned in a substantially vertical plane.

A sampling needle is provided for piercing a septum of a vial containing a sample and aspirating the sample from the vial. The needle may include: a tubular core having a lumen extending therethrough and a piercing end, wherein the tubular core is formed of a bioinert material; a hollow support encircling the tubular core with the piercing end extending outwardly from the support, wherein the support is formed of a rigid material; and a bioinert coating covering a portion of the support adjacent the piercing end, wherein the tubular core and the covering isolates the support from the sample.

An integrated microfluidic unit with pipette adaptation. The integrated microfluidic unit may be accommodated within a pipette tip rack for storage prior to use and may be received by a translating pipette head during use. The number of components required within the laboratory instrument is reduced compared to processes employing discrete microfluidic chips and pipette tips. Processes involving microfluidic devices integrated into the presently disclosed unit are streamlined at least by the elimination of discrete manipulation steps associated with aspirating sample fluid into a pipette tip, then using a discrete chip feeder or manipulator to bring the chip and pipette tip into fluidic communication for transfer of the sample to the chip. The number of consumables is also reduced by the integration of microfluidics with physical features enabling fluid aspiration and unit conveyance. A variety of microfluidic devices and channel configurations may be accommodated.

A sampling system includes a graduated sampling chamber configured for fluid connection to a sample source, a pump device configured for fluid connection with the sampling chamber, and a sterile air filter intermediate the pump device and the sampling chamber, wherein the pump device is selectively actuatable to draw a volume of fluid from the sample source into the sampling chamber.

The present invention discloses an ocean surface water continuous sampling device, the device comprises a support that ascends and descends along the stern, on the support a sampling pipe for drawing and sampling the surface water, and hydraulic tanks for driving the support up and down to send the sampling pipe to where the surface water is are provided, and a buffer mechanism for avoiding damage due to constant water resistance to the sampling pipe during sailing is provided on the support too. Configuration of the depth transducer, control unit and hydraulic tanks, promises surface water accurate and continuous collection during research vessel travelling; the buffer mechanism works effectively in avoiding radial and axial damage to the sampling pipe due to continuous water current resistance, which successfully relieves the resistance, and prolongs sampling pipe life; and automatic surface water collection is realized with the automatic control design.