Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

A display control unit (52) displays a screen for setting sample information on a display unit (8) for each sample placed in a sample placement section (20), and an input processing unit (53) receives information such as a culture name and seeding date and time information input by an operator via an operation unit (7), and stores the information in a storage unit (55). This file is transferred to a data processing unit (4) and stored in a sample information storage unit (40). After analyzing the respective samples in an LC-MS (3), a quantitative analysis unit (42) performs a quantitative analysis based on the obtained data, associates the analysis result with the sample information, and stores the data in an analysis result storage unit (43). As a result, the sample information and the analysis result of the respective samples in the preprocessing stage are associated with each other. Result display processing unit (44) arranges sample information and an analysis result for one sample on the same screen and displays them on display unit (8). With this display, an operator can easily and accurately grasp the correspondence relationship between the sample information and the analysis result of a plurality of sample to be subjected to preprocessing.

An automatic analyzing apparatus is provided which includes a member 401 fixed at a predetermined level which presses down the sample container sealed with the sealing plug that is floated from the rack due to friction between the probe and the sealing plug when pulling out the probe from the sample container sealed with the sealing plug, and a mechanism 402 that pushes down, toward the rack, the sample container sealed with the floated sealing plug in which the sample container sealed with the floated sealing plug is transported by the transport line, and disposed on a path of the transport line until re-inspection is performed after pulling out the probe from the sample container sealed with the sealing plug.

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.

The sample container loading or storing unit includes a sample rack tray and a sample rack tray installation portion on which the sample rack tray is installed, the sample rack tray installation portion includes a claw portion that moves in a contact direction with a sidewall portion of the sample rack tray, the sample rack tray includes a claw guard portion provided on the sidewall portion of the sample rack tray, and the claw guard portion is configured to be separated from the sidewall portion of the sample rack tray by being pushed by a sample rack.

A laboratory instrument comprising a single base plate is presented. The single base plate comprises at least one embedded consumable compartment, an embedded sample processing compartment, an embedded waste compartment, an embedded activation device compartment, an embedded rack receiving compartment, or a combination thereof. A laboratory system and a method adjusting the positioning of at least one pipetting device or handling device of a laboratory instrument or laboratory system are also disclosed.

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.

An automated carousel and system configured for translationally moving a plurality of biological production units in unison along a vertical frame while maintaining a precise alignment of each of the biological production units relative to gravity, and simultaneously providing independent dynamic adjustment of the axial orientation of each of the plurality of biological production units relative to gravity. The automated carousel may be adapted for use with a variety of biological production units supporting cell culture and/or tissue engineering systems in various clinical and laboratory settings and provides for ergonomic use thereof.

A sample analyzing apparatus for performing an optical-based measurement on a sample includes a housing, a first light source, excitation optics, a first light detector, emission optics, and a monitoring system, all of which are disposed in the housing. The monitoring system is configured for monitoring a movable component disposed in the housing. The monitoring system includes one or more light sources for illuminating the movable component, and one or more light detectors for detecting light reflected from the movable component in response to being illuminated.

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.