Systems and methods of identifying reagents loaded into a fluid handling system can comprise programming a protocol for preparing a sample into a controller of the fluid handling system, loading multiple reagent vessels into a carousel of the fluid handling system, imaging individual labels of the multiple reagent vessels with an imaging device to produce label images, comparing information in the label images to identification information located in a database in communication with the controller, and determining if appropriate reagents have been loaded into the carousel to perform the protocol. A fluid handling system can include a deck, a tube holder, an imaging device, a pipettor, a non-transitory computer-readable storage medium and a processor configured to perform the method.

A smear preparing apparatus that operates under selectable operation modes, may include: a smearing unit that prepares smeared slides by smearing samples onto slides; a staining unit that is capable of housing the smeared slides and that performs staining processing by accommodating a staining solution used to stain the samples on the housed smeared slides; a fluid circuit that supplies the staining solution to the staining unit; and a controller that controls the supplying of the staining solution to the staining unit depending on a selected one of the operation modes.

An automatic analyzer is provided wherein degree of freedom in arrangement of a dispensing mechanism and of a unit provided below the dispensing mechanism is improved. The automatic analyzer comprising a dispensing mechanism driving a probe for a specimen or a reagent, wherein the automatic analyzer comprises an arm of two degrees of freedom supporting the probe, a first shaft and a second shaft that support the arm and transmit power to the arm, and a motor that gives power allowing the first and second shafts to be rotated and vertically moved, the second shaft being divided in an axial direction and having different diameters and, at the time of lowering the arm by the power of the motor, divided one of the second shaft being housed inside the other, whereby the second shaft is shortened.

An automated liquid handling system includes a transfer robot unit, a handling module, and a fixing unit which is coupled to a head of the robot unit and on which a pipette assembly is to be mounted, wherein the handling module is provided with a mounting part detachably mounted on the fixing unit. The fixing unit includes a body part, a fixing part hook formed at an upper portion of one side of the body part and a lower protrusion disposed at a lower portion of the one side of the body part, the mounting part includes a body, a movable hook part formed at an upper portion of one side of the body and a lower groove formed at a lower portion of the one side of the body to correspond to the lower protrusion, a catching step is formed at the lower groove, and the lower protrusion extends from the lower portion of the one side of the body part to support the catching step from below, and the movable hook part is hook-coupled to a fixing unit hook.

There is provided a nucleic acid extraction method using a cartridge comprising: (a) a driving part of a nucleic acid extraction device is connected to a control rod module disposed in an inner space of the upper body of a piston and a rotation control module coupled to the lower body of the piston; (b) driving the rotation control module and the control rod module, sequentially sucking sample and reagents from the plurality of chambers separated from each other into an interior space, and discharging the mixture of the interior space into the chamber of the cartridge; and (c) driving the rotation control module and the control rod module to suck the reagent inside the master mix bead chamber of the cartridge into the interior space of the piston upper body and then discharge the mixed reagent to a nucleic acid amplification module.

Device (100) for attesting the operations of an in-vitro diagnostic device (50) comprising: a block (101) for capturing a plurality of frames of the tip (51); a block (102) for storing the plurality of frames; a block (103) for evaluating the right hooking of the tip (51) to the in-vitro diagnostic device (50); a block (104) for evaluating the volume of a liquid contained in the tip (51); a block (105) for carrying out verification before the operation of dispensing the liquid; a block (106) for carrying out a post-dispensing verification; blocks (107, 108) for emitting electronic signals; a block (109) for integrating a system for managing the errors; a block (110) for saving the data; a block (111) for communicating with the in-vitro diagnostic device (50).

The dispensing unit includes a disc, a cartridge, and a dispensing holder. The disc has a disc shape and includes a track region provided with recesses and projections alternately arranged in a radial direction. The cartridge includes a penetration hole, and a well is formed by the penetration hole and the track region in a state in which the cartridge is attached to the disc. The dispensing holder includes a holding part to be inserted into the penetration hole, and a guide hole penetrating the holding part. The guide hole has a truncated cone shape in which a first opening diameter on the holding part side is smaller than a second opening diameter on a side opposite to the holding part, and a center line of the guide hole is located on a line passing through the center of the disc and the center of the well.

The embodiments of the disclosure provide a sample analyzer and a liquid aspiration control method for a sample analyzer. When a liquid aspiration assembly is moving down toward a container, a signal acquisition and analysis assembly acquires and analyzes a first electrical signal; when the first electrical signal meets a first preset condition, the signal acquisition and analysis assembly acquires and analyzes a second electrical signal that is an electrical signal subsequent to the first electrical signal, and determines, according to at least the second electrical signal, whether the second electrical signal meets a second preset condition different from the first preset condition; and when the second electrical signal meets the second preset condition, the signal acquisition and analysis assembly sends information indicating that the liquid aspiration assembly reaches a surface of the liquid. The accuracy of liquid surface detection of the liquid in the container is improved by sending the information indicating that the liquid aspiration assembly reaches a surface of the liquid only when the electrical signal acquired by the signal acquisition and analysis assembly meets the first preset condition and the second preset condition.

A sampling assembly, including a sampling needle, a first pipeline, a second pipeline, a driving member, a first switching member, and a second switching member, is disclosed. The first pipeline is connected between the sampling needle and the first switching member. The second pipeline is connected between the first switching member and the driving member. The first switching member is used for connecting or disconnecting the first pipeline and the second pipeline. The second pipeline is connected, by means of the second switching member, to a negative pressure source. The sampling time of the sampling assembly of the present disclosure is relatively short. The present disclosure further discloses a sample analyzer and a sampling method.

An automatic analyzer includes: a diluted sample holding unit configured to hold dilution containers into which a diluted sample is dispensed; a reaction container holding unit configured to hold reaction containers; a dispensing device configured to dispense the diluted sample from the dilution containers to the reaction containers; a measuring unit configured to perform optical measurement of the diluted sample reacted with reagents corresponding to test items in the reaction containers; a storage unit configured to store information on the diluted sample associated with each of the dilution containers; and a dispensing control unit. The dispensing control unit extracts a dilution container for collecting the diluted sample for retest by searching for the information on the diluted sample stored in the storage unit, and causes the dispensing device to perform a retest dispensing process.