A system for a deep-sea planktonic microorganism in-situ concentration, temperature maintaining and pressure maintaining sampling is provided and includes a sampling cylinder body with double layer structures, the sampling cylinder body is provided with a plug-shaped inner cavity, the plug-shaped inner cavity is provided with a transfer water outlet and a water inlet connected to a water inlet component, the plug-shaped inner cavity is connected to an end cover, the plug-shaped inner cavity is connected to a filter part, the sampling cylinder body is provided with a sampling water outlet, the sampling water outlet is respectively connected to a pressure maintaining device and a water outlet pipe, a temperature maintaining material layer and a temperature control component are connected between the double layer structures, and the temperature control component is electrically connected to a controller. The system can complete sampling on the premise of maintaining in-situ pressure of samples.

Automated pipetting systems and methods are disclosed for aspirating and dispensing fluids, particularly biological samples. In one aspect, a liquid dispenser includes a manifold and one or more pipette channels. The manifold includes a vacuum channel, a pressure channel, and a plurality of lanes. Each lane includes an electrical connector, a port to the pressure channel, and a port to the vacuum channel. The pipette channels can be modular. Each pipette channel includes a single dispense head and can be selectively and independently coupled to any one lane of the plurality of lanes. In some aspects, a valve in the pipette channel is in simultaneous fluid communication with a pressure port and a vacuum port of the manifold. The valve selectively diverts gas under pressure and gas under vacuum to the dispense head in response to control signals received through the electrical connector of the manifold.

There is provided an automatic analyzer that improves the adjustment accuracy of a washing fluid amount by detecting a change in a washing water amount in high sensitivity. An automatic analyzer includes a dispensing mechanism including a dispensing probe configured to dispense a sample or reagent into a reaction container, a washing nozzle configured to discharge a washing fluid to the dispensing probe, and a control unit configured to control the dispensing mechanism. In confirming a liquid amount of the washing fluid, the control unit positions a horizontal position of the dispensing probe on a more downstream side from the washing nozzle in comparison with a horizontal position of the dispensing probe in washing the dispensing probe.

This disclosure is directed to a device and a system for picking a target material from a sample.

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.

Disclosed are a cell analyzer and a method for classifying white blood cells based on an impedance method. The method includes: adding a sample to be analyzed to a white blood cell counting chamber; adding a hemolytic agent to the white blood cell counting chamber at least once; controlling the temperature of the liquid in the white blood cell counting pool to be within a predetermined range; and analyzing the liquid in the white blood cell counting chamber to classify white blood cells into at least four classifications and counting.

A liquid sample analysis method including communicating a specific flow path with an aspirator via a branch flow path, aspirating air from the aspirator, aspirating a liquid sample into the sample supply path from the aspirator so that an entire amount of the aspirated air is accommodated in the branch flow path, communicating a sample extrusion path with a sample port, communicating a sheath fluid supply path with a sheath fluid port, and isolating the branch flow path from both the sample supply path and the specific flow path, extruding the liquid sample in the sample supply path so as to inflow into the sample flow path by causing a sheath fluid to inflow into the sheath fluid flow path from the sheath fluid supply path and causing the sheath fluid to inflow into the sample supply path from the sample extrusion path.

A pH sensor with automatic water storage and replenishment, including a substrate, a working electrode, a reference electrode, a first piezoelectric micropump, a water storage device, and a second piezoelectric micropump. The working electrode, the reference electrode, the first piezoelectric micropump, the water storage device, and the second piezoelectric micropump are arranged on the substrate. The working electrode and the reference electrode are each connected to a bonding pad through an electrode lead. The second piezoelectric micropump, the water storage device, and the first piezoelectric micropump are sequentially communicated, and a liquid flows to the working electrode via an outlet of the first piezoelectric micropump.

A robot accessory and/or device that provides a sample collector device, a sample storage device, and a work surface. Upon activation, the sample collector device performs a full cycle in which an actuator causes the movement (i.e., extension and then retraction) of an actuator arm that simultaneously causes the top link plate, the lance plunger, the plunger guide, and the plunger to likewise move, including the depression and/or compression and release of the pipette. During this full cycle, this single device is able to remotely collect solid, liquid and/or multiphase samples of potentially hazardous materials and reduces human exposure to this hazardous material and dangerous environment.

A device for transferring liquids and liquid samples in certain quantities includes a first housing, a second housing, and a liquid extraction assembly. The first housing includes a first sidewall, a first top wall, an extrusion portion, and a first receiving cavity. The extrusion portion is disposed in the first receiving cavity. The second housing includes a second sidewall, a second top wall, and a second receiving cavity. The first housing is received in the second receiving cavity. The liquid extraction assembly includes a liquid extraction pipe and a liquid extraction head. By thumb or finger pressure, the first housing can be moved into the second receiving cavity to compress the extrusion portion to cause release of a sample, or released to gather a sample.