A storage and incubation device is provided. The device is configured to accommodate a plurality of assay chips, each assay chip including a unique identifier. The device comprises: a plurality of berths each sized to accommodate an assay chip; a communication module configured to receive information about the identifier of each assay chip; a clock timer configured to monitor the timing of the assay within each assay chip; a completion module to manage each assay chip when the assay is complete.

Systems and methods are provided for processing a biological sample. In one embodiment, the method comprises receiving a sample vessel containing the sample; retrieving information from an information storage unit associated with the sample; using said information for selecting at least one cartridge front at least two or more different cartridges, each configured for use with a sample processing device; loading at least one or more reagents onto the cartridge, wherein the one or more reagents to be added are selected based at least in part on the information or instructions derived from the information; and placing the sample vessel in the cartridge.

A 3D ultrasound imaging device including an ultrasound probe assembly and echo analyzer. The ultrasound probe assembly includes a housing and an acoustic window abutted against the housing to form a sealed chamber, wherein the surface of the acoustic window contacts with the breast of the human body to be examined; an ultrasound transducer moves at a first speed back and forth within the sealed chamber and performs high-speed pre-scanning through the acoustic window to obtain initial ultrasound signals; the echo analyzer analyzes the initial ultrasound signals to determine a quality of a ultrasound image acquired by the high speed pre-scanning; and the ultrasound transducer then moves at a second speed to perform another scan to acquire new ultrasound signals. A 3D ultrasound imaging method is also disclosed.

A diagnostic analyzer includes a rotating device, a first optical reader, and a second optical reader. The rotating device includes a first darkened compartment, a second darkened compartment, and an optical path along which the first darkened compartment and the second darkened compartment travel. The first optical reader is operable to read the first darkened compartment and the second optical reader is operable to read the second darkened compartment.

A laboratory distribution system is presented. The system comprises diagnostic laboratory container carriers and a conveyor. The conveyor comprises an endless drive defining a closed-loop conveyor pathway. The system comprises supporting elements attached to the endless drive. The supporting elements receive a container carrier and transport the container carrier in an upright position along a pathway section. The supporting elements are mounted pivotally about a horizontal pivot axis to the drive and structured such that a center of gravity of the supporting element with or without an empty or loaded container carrier is arranged below and vertically aligned with the pivot axis when the supporting element is in an upright position such that each supporting element is free to pivot about the associated pivot axis under the effect of gravitational forces acting on the supporting element for maintaining the supporting elements in an upright position while travelling along the path.

The present invention describes an automated platform for inoculating a variety of receptacles with biological samples for testing and analysis. The lab automation system includes a plurality of modules used to automate the inoculation of media for subsequent analysis. In this regard, the lab automation system has one module to enter specimen/order information and store an inventory of petri dishes. Another module is used to label the sample receptacles with a unique identifier that associates the receptacles with the sample. Yet another module includes a robot for retrieving sample and inoculating the receptacles. The sample inoculation module also includes an apparatus that will receive slides, inoculate those slides, and further process the slides for analysis. Finally, the lab automation system includes a module that streaks the culture media with the sample. Thus, the automated lab system described herein provides consistent samples with minimal input from a lab operator.

An automated sample inspection system is provided with a conveyance line for conveying sample carriers; an empty sample carrier line for conveying empty sample carriers; and a buffer line for temporarily holding empty sample carriers supplied from the empty sample carrier line to the conveyance line. According to the depletion status of the buffer line of each processing system, and the depletion status of other processing systems adjacent to each processing system, the number of empty sample carriers to be conveyed from the empty sample carrier line to the buffer line of each processing system, and the number of empty sample carriers to be conveyed from the empty sample carrier line of each processing system to the empty sample carrier line of another adjacent processing system are determined. Consequently, delays in the processes in the system can be suppressed due to the suppression of the depletion of sample carriers.

Included are: a main body including an installation part in which a cartridge housing a liquid for treating a test substance contained in a specimen is installed and a detector configured to detect the test substance treated with the liquid within the cartridge installed in the installation part; a lid part arranged rotatably on the main body about a shaft so as to open and close the installation part; a biasing part biasing the lid part in an opening direction; and a plurality of regulators each generating resistance against a biasing force in the opening direction at different timing during an opening motion of the lid part.

A test tube rack of an analyzer pipeline includes multiple test tube holders for holding test tubes. The test tube rack of an analyzer pipeline comprises a light blocker configured at a side wall of the test tube rack and across multiple test tube holders. A second feature area is on the light blocker between two adjacent test tube holders, a first feature area is between two adjacent second feature areas and a step gap with a predetermined depth is between the first feature area and a second feature area.

An automation apparatus of an analysis laboratory, for handling support devices able to support containers of biological samples. The automation apparatus includes two main automatic belt conveyors arranged in positions spaced from one another on a floor, and at least one auxiliary automatic belt conveyor. The auxiliary belt conveyor is spaced at a different height with respect to the main conveyors, and is operatively connected to the main conveyors by means of lift devices.