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 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.

Provided is a specimen treatment system that can detect whether a specimen container is uncapped by using a simple mechanism. The specimen treatment system comprises: an automatic analyzer that analyzes a specimen; a pretreatment device that performs a pretreatment on the specimen; and a conveyance passage that conveys, in the automatic analyzer or in the pretreatment device, a specimen container that houses the specimen. The specimen treatment system is characterized by further comprising a single sensor that is disposed so as to be orthogonal to the longitudinal direction of the specimen container and that detects whether the specimen container is uncapped.

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.

Clusters of multiple diagnostic analyzers, as well as, alternatively, to one single analyzer that consists of multiple parallel cores (basic analyzer modules) to provide a scalable and user-friendly system architecture. The invention provides a terminal for loading, identifying and hosting samples and/or consumables to at least two automated analyzer systems, the system comprising a distribution robot with four linear drives and a rotational drive, wherein a first linear drive comprises a sledge that can only move linear and horizontally on a rail; the rotational drive comprises a platform that can rotate around the sledge; a second linear drive comprises a carrier that can only move linear and horizontally on the platform; a third linear drive comprises a hook that can only move linear and horizontally on the carrier; and a fourth linear drive comprises a drive for vertically moving the platform over the sledge.

A status visualization method of a diagnostic laboratory system. The status visualization method includes receiving, at a system controller, computer-readable data comprising analyzers included within the diagnostic laboratory system, and test demand for types of tests and number of the tests to be performed on samples by the analyzers, wherein the analyzers each include consumable items and maintenance items. The method further includes determining, via a walk-away time estimation module executing on the system controller, an estimated walk-away time for the analyzers based upon the test demand and status of the consumable items and maintenance items. Diagnostic laboratory systems with walk-away time estimation are disclosed, as are other aspects.

A method for determining the quality of a hose in an automated analyser system, comprising the steps of collecting data of a wash curve by measuring the light intensity through a hose with an optical sensor during washing of a hose; determining and recording the voltage changes related to changing light intensities; extracting an aspiration time and time for completing of a an aspiration process from said data; determining changes in the data of the most recent wash curves. The disclosure further relates to a device for preforming said method.

An automated analyzer system for biological samples is provided and includes a sample processing system and a controller configured to receive a selection of one of multiple workflows for determining a presence and/or concentration of an analyte in a biological sample and prompt the automated analyzer system to automatically carry out the selected workflow using the sample processing system and output a result classifying the biological sample.

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 system and method and an interconnected laboratory system comprising clinical diagnostic systems are presented. The diagnostic system comprises a sample preparation module, a liquid chromatography (LC) separation module coupled to the sample preparation module via a sample preparation/LC interface, a mass spectrometer (MS) module coupled to the LC separation module via an LC/MS interface, and a result calculation module for identifying and/or quantifying analytes or substances of interest contained in the samples and passed through the LC separation and MS modules. The diagnostic system comprises a controller programmed to monitor operational parameters (1-n) indicative of a performance status of the diagnostic system, to trigger a quality control procedure and/or a maintenance procedure whenever one or more parameters (1-n) of the operational parameters (1-n) is out of specification, and to minimize the quality control and/or maintenance procedures as long as the operational parameters (1-n) remains within specification.