A droplet dispensing device includes an adjustment plate; a first sensor, provided on an upper surface of the adjustment plate and detecting a position of the transparent droplet; a tray, on which one of the well plate and the adjustment plate is detachably mounted; a head part, discharging the transparent droplet; and a CPU, switching an operation mode from one of a first mode and a second mode to the other. In the first mode, the transparent droplet is discharged from the head part toward the well plate, and in the second mode, the transparent droplet is discharged from the head part toward the first sensor. The CPU adjusts the position on the well plate in which the transparent droplet is discharged from the head part in the first mode based on a position of the transparent droplet detected by the first sensor in the second mode.

Systems and methods for use in an in vitro diagnostics setting may include an automation track, a plurality of carriers configured to carry a plurality of sample vessels along the automation track, and a characterization station including a plurality of optical devices. A processor, in communication with the characterization station, can be configured to analyze images to automatically characterize physical attributes related to each carrier and/or sample vessel. A method may include receiving a plurality of images from a plurality of optical devices of a characterization station, wherein the plurality of images comprise images from a plurality of perspectives of a sample vessel being transported by a carrier, automatically analyzing the plurality of images, using a processor, to determine certain characteristics of the sample vessel, and automatically associating the characteristics of the sample vessel with the carrier in a database.

A method of handling laboratory sample containers is presented. The method comprises moving a laboratory sample container to a target position. The target position is a position at which the laboratory sample container is inserted into a corresponding orifice of a laboratory sample container rack provided that the laboratory sample container rack is placed at an intended position. The laboratory sample container is prevented from moving horizontally more than a predetermined horizontal distance if inserted into the corresponding orifice of the laboratory sample container rack. The method also comprises applying a force in a horizontal direction (xy) to the laboratory sample container, determining if the laboratory sample container moves in the horizontal direction (xy) more than the predetermined horizontal distance, and performing an error procedure if it is determined that the laboratory sample container moves in the horizontal direction (xy) more than the predetermined horizontal distance.

A centering unit for diagnostics laboratory transporting compartment is presented. The centering unit for diagnostics laboratory transporting compartment comprises at least two arms with grippers for centering diagnostics laboratory transporting compartments of different diameters. For accurate and reliable centering of laboratory transporting compartments, the two arms are biased with a single elastic member. A laboratory system and a method for centering diagnostics laboratory transporting compartment and diagnostics laboratory transporting compartment holder are also disclosed.

Proposed is a technique for facilitating work of cause investigation of a defect by an operator. The present disclosure proposes an automatic analyzer including: a reagent dispensing unit configured to aspirate a reagent from a reagent vessel that contains the reagent, and discharge the reagent into a reaction vessel that contains a reaction liquid containing a sample; a storage unit configured to store a type of the sample and concentration-related information determined for each type of the sample and related to a concentration of a component to be measured contained in the sample; a detection unit configured to detect a measurement concentration that is the concentration of the component to be measured contained in the reaction liquid; and a determination unit configured to determine whether an abnormality occurs in the reagent vessel based on the concentration-related information and the measurement concentration.

An automatic analyzing system includes an automatic analyzer, a conveying portion for a vessel that accommodates a liquid, a loading portion that receives the vessel from the conveying portion and loads the vessel into the analyzer, and a correction portion that performs position correction between the conveying portion and the loading portion in order for the conveying portion to be able to deliver the vessel to the loading portion. The correction portion includes a hole provided in the loading portion and for constraining rotation motion, one rotation shaft or more, an extension and contraction portion that is provided in the loading portion and generates tension that holds a rotation angle constant, and a member that is provided in the conveying portion and constrains the rotation motion. By inserting the end of the member into the hole, the position correction between the conveying portion and the loading portion is performed.

A receptacle-supporting puck includes spring-biased fingers arranged about a vertical axis, each finger having a contact surface to contact a receptacle seated in the puck. A supporting disc of the puck includes a disc sidewall projecting from a base and defining a pocket for seating a receptacle, first cavities in the base extending toward the vertical axis, and a puck passageway extending through opposed portions of the disc sidewall transversely to and offset from the vertical axis. Each finger is rotatably coupled to the supporting disc at a corresponding first cavity. A synchronization disc is positioned in the pocket, and each of the fingers is coupled to the synchronization disc such that the contact surfaces of the fingers move synchronously toward and away from the vertical axis. A retaining ring couples the fingers, the supporting disc, and the synchronization disc together.

A receptacle delivery system includes a carriage configured to move from a first to a second location of an instrument. The carriage may be configured to removably support a receptacle and may include a receptacle clamping mechanism. The receptacle mechanism may be configured to apply a clamping force to the receptacle as the carriage moves from the first to the second location and release the clamping force as the carriage moves from the second to the first location.

A method of delivering a receptacle to an instrument includes the steps of supporting a receptacle containing a fluid on a carrier, transporting the carrier supporting the receptacle on a conveyor extending adjacent to each of a plurality of instruments, transferring the receptacle from the carrier to a puck supported on a carriage when the carriage is positioned at a first location, moving the carriage with the receptacle seated in the puck from the first location to a second location within an instrument of the plurality of instruments, and drawing at least a portion of the fluid from the receptacle seated in the puck into a tip associated with a fluid extraction device of the instrument when the carriage is positioned at the second location.

Luminescence test measurements are conducted using an assay module having integrated electrodes with a reader apparatus adapted to receive assay modules, induce luminescence, preferably electrode induced luminescence, in the wells or assay regions of the assay modules and measure the induced luminescence.