A sample input interface for inputting samples into a detecting unit of an in-vitro diagnostic analyzer. The sample input interface comprises a sample input port comprising an outer input-port side configured for plugging-in an open end of a sample container and an inner input-port side, an aspiration needle comprising an upstream end and a downstream end, where the downstream end is fluidically connected or connectable to the detecting unit and where the upstream end is configured to alternately couple to the inner input-port side and to a fluid supply port. The outer input-port side is further configured to alternately couple to a fluid supply port while the upstream end of the aspiration needle is coupled to the inner input-port side in order to rinse the sample input port with fluid aspirated by the aspiration needle from a fluid supply unit via the sample input port.

Systems and methods that enable automated processing of specimens carried on microscope slides are described herein. Aspects of the technology are directed, for example, to automated slide processing apparatuses capable of dispensing liquids onto microscope slides. Additional aspects of the technology are directed to methods of replacing a reagent pipette in automated slide processing apparatuses. The apparatus can include, for example, a reagent pipette assembly including a reagent pipette moveable between at least one loading position for obtaining reagent from a reagent container at a filling station and at least one dispense position. The apparatus can also include a retainer for releasably securing the reagent pipette. In some embodiments, the reagent pipette assembly includes a locking mechanism for transitioning the retainer from an open configuration for receiving a pipette and a closed configuration for securing a pipette, in e.g., an aligned position within the retainer.

A sample dispensing mechanism configured to dispense a sample and a reagent to the reaction vessel at a first dispensing position and the reaction cell positioned at a second dispensing position; a second reagent vessel disposed on a track of the sample dispensing mechanism; and a control unit configured to control the sample dispensing mechanism, in which the control unit is configured to, based on information on presence or absence of incubation of an analysis item, control the sample dispensing mechanism to dispense a sample and a reagent to the reaction vessel positioned at the first dispensing position in a case where the incubation is not required by the analysis item, and control the sample dispensing mechanism to dispense a sample to the reaction cell positioned at the second dispensing position in a case where the incubation is required by the analysis item.

Provided is an automatic analysis device that reduces the used water amount when cleaning the outside of a probe. An automatic analysis device, including a probe that performs suction and discharge of a sample or a reagent and a cleaning nozzle that discharges cleaning water toward the outside of the probe, includes a first discharging step of starting discharge of the cleaning water from the cleaning nozzle when the tip of the probe is at a first height position and a second discharging step of starting discharge of the cleaning water from the cleaning nozzle when the tip of the probe is at a second height position higher than the first height position, and is provided with a discharge stopping step of stopping the discharge of the cleaning water from the cleaning nozzle between the first discharging step and the second discharging step.

Provided are an automated analyzer for analyzing a substance contained in an unknown sample and a liquid reservoir, the analyzer and the reservoir being capable of saving users' operation without remarkably increasing the number of components. A flow path outlet of an overflow portion of the liquid reservoirs projects closer to the inner circumferential side of a drain flow path than to an inner circumferential surface side of an outer wall of the drain flow path serving as a destination to which liquid overflows. In addition, the flow path outlet projects so as to come into contact with an outer wall of the inner pipe. The flow path outlet of the overflow portion projects into the drain flow path so as to be located below an upper end of the outer wall of the drain flow path.

A wash station for use in a clinical analyzer of an in vitro diagnostics (IVD) environment for cleaning a probe comprises a basin, a vertically-elongated conduit, an inlet port, and a helix insert. The vertically-elongated conduit is attached to the interior of the basin. The inlet port is connected to a bottom portion of the basin. The inlet port is sized to receive and secure a wash feed line that propels a wash fluid upward through the vertically-elongated conduit. The helix insert is positioned within the vertically-elongated conduit and sized to allow insertion of the probe through a center portion of the helix insert for cleaning. The helix insert causes the wash fluid to flow in a helical shape around the probe as it is transported through the vertically-elongated conduit, thereby cleaning the probe.

An analysis unit for quantitating detection target substances bound to antibodies includes wells and inclination parts. The wells each have a hole-like shape defined by an opening, an inner circumferential surface, and a bottom. The inclination parts each have an inclined surface connected to the inner circumferential surface and inclined downward such that whose height with respect to the bottom decreases as a distance from an outer circumferential side of the well increases.

A soil fractionation system can include a plurality of sample racks propelled by a drive system. Each sample rack can include a sample tube for holding a soil sample and a filter cup for receiving an extracted fraction of the soil sample. An extractor module of the fractionation system can include an extractor assembly and a filter assembly. A control system can control the relative positioning of the plurality of sample racks via the drive system, the relative movement between the extractor assembly and the sample tube, and the relative movement between the filter assembly and the filter cup.

Provided is an automatic analyzer that reduces a risk of damage due to contact with a stirring paddle during maintenance and the like, and realizes miniaturization and simplification. A cleaning tank 181 configured to clean the stirring paddle, a standby position 182 configured to make the stirring paddle which is juxtaposed to the cleaning tank wait, and an inflow port 183 configured to flow cleaning water into the cleaning tank are provided, and the standby position 182 is arranged so that the cleaning water overflowing from the cleaning tank 181 overflows 194 to the standby position 182.

A sampling needle (2) having a suction port at a tip, a movement mechanism (4) that moves the needle (2) at least in a vertical direction while holding the needle (2) in a state where the suction port faces vertically downward, a suction mechanism (6) for sucking liquid through the needle (2), a controller (10) configured to control operation of the movement mechanism (4) and the suction mechanism (6) are included. In sampling of liquid from a container (16) whose upper surface is opened, the controller (10) is configured to execute an inserting step of inserting the tip of the needle (2) into the liquid in the container (16) by lowering the needle (2) from above the container (16), a sucking step of sucking a predetermined amount of the liquid from the suction port of the needle (2) after the inserting step is completed, a pulling up step of pulling up the needle (2) from the liquid to position the suction port above a liquid level of the liquid after the sucking step is completed, and a shaking-off step of repeating shaking-off operation of lowering and suddenly stopping the needle (2) a plurality of times with standby time in which the needle (2) is completely stopped or raised in between while maintaining a state where the suction port is positioned above the liquid level after the pulling up step is completed.