A microfluidic system includes a chip holder that holds a microchip including a plurality of reservoirs, a chip cover, a sealing member; a dispensing probe, a suction mechanism, a first storage where a first cleaning solution is stored, a second storage where a second cleaning solution is stored, a pump, a channel switch, and a controller. The channel switch is configured to switch between a channel through which the first cleaning solution is suctioned from the first storage and a channel through which the second cleaning solution is suctioned from the second storage. The controller controls operations of the channel switch and the pump.

A cleaning water flow velocity during nozzle cleaning is momentarily changed by using a pressure changing mechanism, for example, a syringe. That is, after the start of cleaning, a solenoid valve is opened, and an aspirating operation of the syringe is momentarily performed by a fixed amount in a state where a flow of cleaning water in a nozzle is developed, whereby a nozzle flow velocity is momentarily decelerated. Immediately thereafter, the syringe is pushed back to a home position again, and the flow velocity in the nozzle is accelerated again. A cleaning effect can be improved by performing transition of velocity distribution to various states. Flow velocity control by the pressure changing mechanism can be realized without inhibiting a dispensing cycle, and the cleaning effect of the nozzle can be improved without changing the pressure of a liquid feeding pump or extending the cleaning time.

Provided is a technique related to an automatic analyzer and capable of ensuring cleaning performance of a reaction container by a cleaning process including a tip suction step, and preventing decrease in analysis accuracy or improving the analysis accuracy. The automatic analyzer includes a control apparatus, a block suction mechanism that moves a suction nozzle and a suction block for suctioning a liquid in the reaction container up and down and suctions the liquid, and a block cleaning mechanism for cleaning the suction block. After receiving an analysis request, the control apparatus causes, in a tip suction step that is provided before an analysis step and is a last step of a cleaning step, both suction of the liquid by the block suction mechanism and cleaning of the suction block by the block cleaning mechanism to be performed in a first step, and then only the suction of the liquid by the block suction mechanism to be performed in a second step including one or more cycles; and causes the analysis step to be performed using the reaction container in which the second step is performed.

There is provided an automatic analysis device with a structure in which a measurement unit is less susceptible to disturbance as compared to a device in the related art, and a method of designing the automatic analysis device. A first rotation axis 301 of a reaction disk 1, a second rotation axis 302 of a reagent disk 9, and a measurement unit are arranged on the same straight line 311 when an automatic analysis device 100 is viewed from an upper surface side, the first rotation axis 301 of the reaction disk 1 is arranged between the second rotation axis 302 of the reagent disk 9 and the measurement unit, and the measurement unit is arranged on a front side to be accessed by a user of the automatic analysis device 100.

A washing device comprises a manifold dispenser comprising at least one liquid input and a plurality of liquid outputs that operably direct fluid to contact a plurality of laboratory consumables held by a rack in the washing device, an ultra-violet (UV) light source, and a plurality of fiber optic channels coupled to the UV light source, each of the fiber optic channels extending into a corresponding one of the liquid outputs. The plurality of liquid outputs may each comprise a nozzle having an opening into which a respective one of the plurality of fiber optic channels extends.

A seal pack of a sample manager of a liquid chromatography system having a plurality of wash flow pathways fluidically connected to a central pathway that accommodates a sample needle, wherein a first wash flow pathway is vertically offset from a second wash flow pathway, such that a wash solution flows axially along an exterior surface of the sample needle in a vertical direction to wash the sample needle when flowing from the first wash flow pathway to the vertically offset second wash flow pathway, is provided. Furthermore, an autosampler and associated methods are also provided.

The object of the invention is to avoid a decrease in dispensing accuracy of a sample, a reagent, or the like as a temperature changes. In an automatic analyzer, a dispensing nozzle sucks the sample from a sample container holding the sample and discharges the sample to a reaction container. A syringe pump controls an amount of change in a volume of water. A first pipe connects the dispensing nozzle and the syringe pump. An electromagnetic valve flows or stops the water. A second pipe connects the electromagnetic valve and the syringe pump. A branch pipe branches the water. A third pipe connects the electromagnetic valve and the branch pipe. A case accommodates at least the syringe pump, the first pipe, the electromagnetic valve, the second pipe, the branch pipe, and the third pipe. Further, the third pipe includes a heat exchange unit that performs heat exchange of the water.

An object of the present invention is to provide an automatic analyzer that can decrease the frequency of cleaning as compared to the past by suppressing breeding of bacteria and the like in a buffer tank as compared to the past and can reduce maintenance work time of an operator. Provided is an automatic analyzer comprising: an analysis module 20 that analyzes a specimen; and a supply system that supplies a liquid to the analysis module 20, wherein the supply system includes: a buffer tank 3 that temporarily stores pure water supplied from a pure water production device 50 outside of the analyzer; a supply channel 7 through which the pure water in the buffer tank 3 is sent to the analysis module 20; a circulation water pump 4 that feeds the pure water in the buffer tank 3; a circulation channel 8 through which the pure water discharged from the circulation water pump 4 is returned to the buffer tank 3; a sterilization mechanism 5 that sterilizes the pure water in the supply system; and a control unit 30 that controls an operation of each device in the supply system.

The present subject matter relates to systems and methods for the formulation of inks from stock solutions in which a liquid handler is configured to draw samples from a plurality of solution components and mix the components together to create one or more ink formulations, and a dispensing robot is configured to transfer the one or more ink formulations to a common substrate to form one or more material samples or a coating element in communication with the liquid handler is configured to transfer the one or more ink formulations to a common substrate to form one or more material samples. A controller in communication with each of the liquid handler and the dispensing robot can be configured to coordinate the creation and transfer of the one or more ink formulations. In addition, the one or more material samples can be analyzed using one or more characterization instrument configured to characterize the material samples on the common substrate.

An automatic sample injection device includes: an; and a management device. The injector includes: a turret; and a vial sensor. The management device includes: a condition setting unit configured to set a condition relating to a type of a vial to be used in the sample injection operation, based on information input by a user; and a vial determination unit configured to determine, before the injector initiates the sample injection operation, whether or not there is a missing vial on the turret out of the vials of the plurality of types set to be used in the sample injection operation under a condition set by the condition setting unit, by using a detection result of the vial sensor.