The present invention provides a disposable ultra-filtration system comprising a disposable pipetting tip and a disposable ultra-filtration cartridge, wherein the cartridge includes a membrane filtration chamber and a dead-end channel. In use, a piston in the pipette pressurizes air within the channel; the pressurized air can subsequently move the piston and cause a reverse flow back through the membrane of the cartridge, unplugging the pores thereof. Also disclosed is an automated workstation incorporating the disposable ultra-filtration system, and a system comprising the automated workstation, useful for measuring the free therapeutic drug concentration and free hormone concentration in a sample.

An apparatus and system including an apparatus to identify an identifier on a tissue cassette in an assembly of a plurality of tissue cassettes including a light source operable to illuminate a plurality of tissue cassettes; a sensor operable to automatically capture an identifier on an individual tissue cassette or an image of the plurality of tissue cassettes in the assembly; and where the sensor is operable to capture reflected light from the light source of an image of the plurality of tissue cassettes, a converter to convert image data into an electronic signal. The system may include a processor operable to compare an identifier with a tissue processing protocol. A method including sensing identifiers on tissue cassettes each containing a tissue sample in an assembly comprising a plurality of tissue cassettes; and determining or verifying a tissue processing protocol of a tissue sample based on the sensed identifier.

An analyzer is disclosed. The analyzer comprises a rack slot configured to receive at least one rack, wherein the rack slot comprises a front end, at which the rack is manually loadable into the rack slot, and a rear end, which is opposite to the front end and at which the rack is fully receivable in the rack slot, and a spring device arranged at the rear end, wherein the spring device is configured to provide a biasing force towards the front end, wherein the biasing force is adapted to move the rack towards the front end if not fully received in the rack slot, wherein the spring device is configured to fix the rack in a final position if the rack is fully received in the rack slot. Further, a method for loading a rack into a rack slot of an analyzer and a system comprising an analyzer and a computer controller are disclosed.

In a solid phase extraction (SPE) apparatus, a cartridge housing tray houses a plurality of SPE cartridges. A liquid loading assembly applies liquid samples and SPE solutions into the plurality of cartridges. A liquid drawing assembly forces the liquid samples and the SPE solutions once they are applied to pass through the plurality of the SPE cartridges.

A GUI is used to schedule a set of tasks for one or more robots to test samples using one or more instruments. A set of drivers are used to map instructions for the robots and instruments form a standardized format to a set of instrument/robot-specific formats. Using the standardized formats enables support for new types of robot and/or instrument to be easily added to the system. The robots and instruments generate test results from samples according to the instructions. Information about the testing may be stored in conjunction with user identifiers and other metadata to provide a verifiable audit trail across the instruments and robots.

An automated pre-analytical processing method and an apparatus for pre-analytical processing of samples to be forwarded to an adjacent analyzer for analysis. Rack label information is read and communicated to a processor. From the rack label information, the processor determines where to route the rack. The pre-analytical system has a rack robot that conveys racks to discrete locations depending upon the routing information assigned to the rack by the processor. The pre-analytical system has an automated station that reads the labels of individual sample containers in the rack that are brought to the automated station on instructions from the processor. Depending on the type of sample container and the type of sample disposed therein, the samples are either prepared for analysis by the automated station or the sample containers are directly passed through the automated station. Prepared samples and passed through samples are passed individually to a batching rack.

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 storage system having racks and an outer container that receives the racks, each rack receiving a plurality of sample boxes, each box having a wireless ID tag. In certain embodiments, the storage system has reader electronics external to and distinct from the racks and that directly read the wireless ID tag of each box in at least one rack without relying on any reader electronics of any rack. In other embodiments, each rack has a set of rack reader electronics that read the wireless ID tag of each box in at least one rack, and the storage system has at least one removable reader access device removably connectable to the set of rack reader electronics of a rack in order to transmit the ID number of the wireless ID tag of each box in the rack outside of the outer container.

A parallel processing system for processing samples is described. In one embodiment, the parallel processing system includes an instrument interface parallel controller to control a tray motor driving system, a close-loop heater control and direction system, a magnetic particle transfer system, a reagent release system, a reagent pre-mix pumping system and a wash buffer pumping system.

A blood analyzer according to one or more embodiments may include: a specimen preparation part that prepares a measurement specimen by mixing a reagent into a blood preparation; a measurement part that measures the measurement specimen; a measurement mode selection unit that receives an input of a type of blood preparation as a measurement target selected from a plurality of types of blood preparations; and a controller. The controller may cause the specimen preparation part to prepare the measurement specimen depending on the selected type of blood preparation.