The invention relates to a device for sampling from bioreactors, comprising a rising line (1) connectable to a bioreactor, a tap line (2), and a withdrawal line (3), which are connected to a T-like connection. The withdrawal line (3) comprises a first shut-off valve (4), the tap line (2) is connected to a positive pressure source (5), and the withdrawal line (3) is connected to a pump (7). In the device for sampling, the positive pressure source (5), the pump (7), and the first shut-off valve (4) are controllable in an automated manner via a control unit (13). The invention furthermore relates to a method for using such a device for sampling.

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.

The disclosed methods for preparing cytological samples may include placing a cytological sample in a concave filter in a filtration system, applying a negative pressure to an outer side of the concave filter with a vacuum device to withdraw a liquid from the cytological sample, applying a sectionable matrix material over the filtered cellular material within the concave filter, and removing an assembly including the filtered cellular material and the sectionable matrix material from the filtration system. Various other related methods, systems, and materials are also disclosed.

A fluid sampling system and fluid sampling vessel therefor permit sampling of fluids from industrial machines or fluid storage containers using one hand while being able to retain sampled fluids without spillage and without permitting contaminants to enter the sampling bottle before, during and/or after sampling.

A cryogenic liquid sampling system including a chamber having affixed therein a sample pump to pull a cryogenic liquid sample from an external source and an enclosure. The enclosure includes a supply port to receive an input stream of a gas, an input port connected to the chamber via a vacuum line, a sample pump port connected to the chamber via a pump line and configured to feed therethrough gas received at the supply port to the sample pump, a vacuum device connected to the input port and configured to generate a vacuum within the chamber by pulling air from the vacuum line, and processing circuitry to control the vacuum device and the sample pump to perform transfer of a cryogenic liquid sample from the external source to an external device.

Provided are low flow groundwater fluid sampling systems and related methods of collecting fluid samples, including a low flow pump, flow cell, waste container and a communication device in communication with those components. In this manner, the low flow pump may be controlled to ensure a desired constant flow-rate is achieved, and a remote operator may monitor the status of fluid being pumped to the flow cell with the communication device, such as with a portable electronic device, including a smart phone. The system may alert the operator that fluid is ready to be collected for sampling, including at an off-site laboratory. Particularly useful applications are for monitoring groundwater quality and contamination.

To accurately analyze measurement target particles in each specimen, while reducing variation in dispensing amounts of specimens which is caused by different viscosities of the respective specimens. A sample preparing apparatus 1 includes: a measurement section 2 configured to measure a specimen obtained from a specimen container 10, and obtain viscosity information relating to viscosity of the specimen; a sample preparation section 3 configured to prepare a measurement sample by aspirating the specimen from the specimen container 10, discharging the specimen into a mixing container 11, and mixing the specimen with a labeling substance in the mixing container 11; and a control section 4 configured to determine, on the basis of viscosity information, at least one of an aspiration condition for aspirating the specimen and a discharge condition for discharging the specimen, and control the sample preparation section 3.

Aspiration of a pipette arrangement is initiated. A sensor arrangement senses a least one prevailing first parameter that is dependent from the effect in the pipette arrangement during initiating and upholding the suctioning action. This at least one parameter is analyzed in an analyzing stage. From a result of this analysis and in a determining stage at least one test criterium TC for at least one further parameter as sensed by the sensor arrangement is determined. In a checking stage there is checked whether this further parameter fulfills the at least one test criterium.

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.

The present technology is directed to extraction devices, systems, and methods for controllably withdrawing and transferring fluid samples, such as blood, from a sample collection container to a testing device. For example, some embodiments of the present technology provide fluid extraction devices that include a fluid control module, a housing containing a receiving element and a suction element, and an actuator. To transfer blood from a sample collection container to a testing device, a user places the sample collection container over the receiving element and inserts the testing device into an outlet of the fluid control module. The user then pushes a lever or otherwise actuates the actuator, which automatically withdraws a predetermined volume of blood from the sample collection container and transfers it to the testing device positioned at the outlet of the fluid control module.