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. A number of the plurality of liquid outputs being at least equal to a number of the plurality of laboratory consumables such that each liquid output of the plurality of liquid outputs operably directs the liquid at a corresponding laboratory consumable of the plurality of laboratory consumables.

There is provided a cool box for use in an automatic analyzer. The cool box has a box body and an air circulator. The box body has a receiving space capable of accommodating therein receptacles for analytes or reagents. The circulator has an intake portion, a fan, and an exhaust portion and operates to circulate air in the receiving space by rotation of the fan. The circulator further includes an inhibitor removing agent retaining portion on which a pouch is set. The pouch contains an analysis inhibitor removing agent for removing components (analysis inhibitor) which adversely affect or inhibit analysis of the analytes.

Stable operation of an ultrasonic vibrator of an ultrasonic cleaner and scattering prevention of a washing liquid are provided. The ultrasonic cleaner includes a washing tank 206 in which a washing liquid is reserved; an ultrasonic vibrator 205; a vibration head 209 provided with a neck 304 extended from the ultrasonic vibrator to the washing tank and a tip end portion 210 having a cylindrical hole 211 whose longitudinal direction is oriented to a perpendicular direction; and a first cover 601 having an opening corresponding to the neck and the cylindrical hole, in which the first cover is arranged to a height in contact with a liquid surface of the washing liquid such that it covers the washing tank.

Provided is a glycated hemoglobin measuring apparatus. The apparatus for measuring glycated hemoglobin includes a cartridge for receiving blood and a plurality of chemicals, a rotating tray for rotating the cartridge, wherein the cartridge is disposed inside the rotating tray, a driver having a nozzle disposed above the cartridge and movable in a vertical direction, and a measurement unit located above the cartridge and measuring glycated hemoglobin of the blood, wherein the driver sucks at least one of the blood, the plurality of chemicals, and mixed solution of the blood and the plurality of chemicals into the nozzle or discharges the sucked at least one into the cartridge such that the blood is chemically treated through the plurality of chemicals.

An apparatus for decontaminating and storing lab instruments such as pipettes. A carousel feature of the apparatus provides convenient access and allows multiple items to be decontaminated at the same time. The ultraviolet lamp directs UV radiation to surface contaminations of the instruments and effectively eliminates various microorganisms.

A centrifuge for cleaning a reaction vessel unit, having a rotor for holding at least one reaction vessel unit with its opening(s) directed outwardly, a motor for rotating the rotor around a rotation axis, a housing having a substantially cylindrical inner surface, wherein a drain is provided for discharging fluid expelled from the reaction vessel unit, wherein a gap is provided between the inner surface and the rotor so that by rotating the rotor a wind is generated which drives the expelled fluid on the inner surface to the drain wherein an aspiration pump is connected to the drain for discharging fluid.

An autoclaving microplate washing system for cells and non-adhering three-dimensional (3D) cell cultures includes one or more peristaltic pumps for controlling the dispensing of washing fluid and the evacuation of fluid from microwells to gently wash the cells.

A fluid-holding vessel (28) with a surface tension reducing geometry which comprises an inner surface having striations (24) and a fluid transfer method are disclosed and described. The fluid-holding vessel (28) may be a test tube that is used in combination with a cap (20), which is penetrable by a fluid transfer device (11) of an automated analyzer (10) used to transfer fluids to or from the striated test tube, where the tube and cap may remain physically and sealably associated during a fluid transfer. The automated analyzer (10) may be used in combination with the fluid-holding vessel (28) as disclosed and described herein, in which the surface tension reducing geometry (24, 26) of the vessel (28) addresses an aspiration problem of a liquid (18) dispensed therefrom automatically by the automated analyzer (10), e.g., into a sample cup.

Disclosed herein are high-throughput sample processing systems and waste management systems, and methods of using the same.

A wash station comprises a wash nozzle for cleaning an exterior portion of a probe and a basin allowing for waste fluid to be collected. The wash nozzle comprises a vertically-elongate cavity with side slits on opposing side portions. A fluid inlet port may be connected to a side portion of the cavity to provide fluid. Fluid may additionally or alternatively come from within the probe. The basin comprises an elongate body with an opened end to receive and secure the wash nozzle. One or more access slots may be provided on opposing side portions of the basin. The probe passes through an access slot or over a portion of the basin and through a side slit of the nozzle to enter the cavity for cleaning. A geometry of the cavity allows the wash nozzle to fill to a predetermined level while waste fluid flows out through the side slits.