Provided herein are automated apparatus for the identification of microorganisms in various samples. The disclosure solves existing challenges encountered in identifying and distinguishing various types of microorganisms, including viruses and bacteria in a timely, efficient, and automated manner by sequencing.

The present invention relates to an automated analytical system and an automated method for separating and detecting an analyte, as well as an automated analytical instrument.

A system for loading pipette tips. A system for accommodating pipette tips is provided, comprising a tray having openings for accommodating pipette tips in a plate, wherein the openings have at their upper end a surrounding contour which has curved surface area corresponding to a section of a spherical washer, and pipette tips having at their upper end an offset forming a contact surface for the surrounding contour of the tray's opening, wherein the shape of the contact surface corresponds to the section of a spherical washer so that the centers of both spheres of surrounding contour and contact surface are congruent

A system is disclosed for measuring head framing and tip straightness in a liquid handler. The present system uses a test plate, having an upper surface formed of clay or other impressionable material. The test plate may be placed at a liquid handling station. Pipette tips may then be loaded onto the head, and the head positioned at the station including the test plate. The head may be actuated in the z-direction so that the tips leave an imprint in the upper surface of the test plate. The imprint of the tips on the test plate may then be analyzed using any of a variety of measurement techniques to determine head framing alignment or misalignment.

Embodiments of lab automation workstations are disclosed in which the pod that performs pipetting operations is integrated with pipette tip-loading functionality. To generate the necessary tip-loading force, a dual drive system is used that is symmetric about the Y-axis to allow for offset or partial tip box loads by dynamically centering the drive force (e.g., the tip-loading force) over the reaction load. This minimizes the need for oversized linear motion components while still allowing for the generation of high tip-loading forces needed to properly load a large number of pipette tips simultaneously.

A radiosynthesis system is disclosed that leverages droplet microfluidic radiosynthesis and its inherent advantages including reduction of reagent consumption and the ability to achieve high molar activity even when using low starting radioactivity. The radiosynthesis system enables the parallel synthesis of radiolabeled compounds using droplet-sized reaction volumes. In some embodiments, a single heater is used to create multiple reaction or synthesis sites. In other embodiments, separate heaters are used to create independently-controlled heating conditions at the multiple reaction or synthesis sites. In one embodiment, a four-heater setup was developed that utilizes a multi-reaction microfluidic chip and was assessed for the suitability with high-throughput radiosynthesis optimization. Replicates of several radiochemical operations including the full synthesis of various PET tracers revealed the platform to have high repeatability (e.g., consistent fluorination efficiency). The system may also be used for synthesis optimization.

The present invention addresses to an automated gas injection system in vials with rubber septa, for simultaneous injection of gas in 24 or more positions, with injection pressure control and/or overpressure detection, applied to mass spectrometry analyses and/or gas chromatography. The present invention can be used, for example, in isotopic analyses of geological materials in equipment with carbonate extraction units, in the cleaning and decontamination of tubes to be used in isotopic or chromatographic analyses, and in the removal of contaminants from steam drag or by continuous flow, or coming from the free space of vials or tubes in the analyses of organic and inorganic materials.

The application of this invention allows reducing the current times of routine purge (flush) of at very least 3 minutes for every 2 positions (72 positions in total and final time of 108 minutes, in a batch of samples) to a total of 96 positions in 3 minutes, with a reduction of 12 times or more in the flush time, which implies greater analytical capacity to the laboratory, lower external costs of sending samples, less time to obtain results, with technology that is easy to implement in universities and research centers in general, in addition to increasing the lifespan of rubber septa.

A configurable washing arrangement (176) washes away at least unreacted components (230, 630) of patient samples (224, 624) from a reaction cell (220, 320) with a multiple number of wash actions (206, 210, 606). The configurable washing arrangement is suitable for use with an immunoassay diagnostic system (100) and washes the reaction cell within a predetermined timed sequence (Tww). The number of the wash actions correspond with an assay type of a plurality of assay types (200, 600). The various number of wash actions may be selected without compromising overall process speed. The immunoassay diagnostic system is configured to perform the plurality of the assay types and thereby detect analytes (244, 644) in patient samples (224, 624) by at least combining each of the patient samples with at least one reagent (216, 232, 616) in the reaction cell.

Provided herein are automated apparatus and methods for the identification of microorganisms in various samples. The disclosure solves existing challenges encountered in identifying and distinguishing various types of microorganisms, including viruses and bacteria in a timely, efficient, and automated manner by library preparation and sequencing.

A flow cell applicator system can include a flow cell applicator including multiple flow cells to deposit multiple substance spots on a deposition surface, and a positioning assembly to position, to dock, and to unlock the multiple flow cells relative to the deposition surface. The substance spots can be depositable when the multiple flow cells are docked on the deposition surface. The flow cell applicator system can also include a spot deposition identifier operably associated with a processor to: record data related to substance spots as applied on the deposition surface, identify data related to substance spots previously deposited on the deposition surface, or both.