A dosing module (137) in an agricultural environment, arranged to apply a milk sample of an animal (100) onto a dry stick (180a, 180b, 180c). The dosing module (137) includes a milk insertion connection (340) arranged to receive milk; a needle (350) configured to receive the milk and apply the received milk to the dry stick (180a, 180b, 180c); a first pump (611), configured to provide milk from the milk insertion connection (340) to the needle (350); and a position adjustment mechanism (510) configured to adjust the needle (350) between a retracted position (α) above the dry stick (180a, 180b, 180c) when dosing milk to the dry stick (180a, 180b, 180c), and at an extended position (β) when flushing milk through the needle (350); and an evacuator (195) arranged to intercept liquid output by the needle (350).

Embodiments described herein relate to an apparatus for positioning and securing an excised biological tissue specimen for imaging and analysis. In some embodiments, an apparatus includes a sample bag defining an inner volume configured to receive a biological tissue sample, and a sealing member coupled to the sample bag. An imaging window is disposed and configured to be placed in contact with at least a portion of the biological tissue sample, and a positioning member is coupled to the imaging window and is configured to be disposed against the sealing member to substantially seal the inner volume. The positioning member includes a vacuum port disposed and configured to be aligned with a vacuum source to withdraw air from the inner volume of the sample bag.

The presence of analytes can be detected in the bodily fluid using Electrochemical Impedance Spectroscopy (EIS) or Electrochemical Capacitance Spectroscopy (ECS) in devices, such as handheld point-of-care devices. The devices, as well as systems and methods, utilize using Electrochemical Impedance Spectroscopy (EIS) or Electrochemical Capacitance Spectroscopy (EIS) in combination with an antibody or other target-capturing molecule on a working electrode. Imaginary impedance or phase shift, as well as background subtraction, also may be utilized.

Disclosed is a loading machine for slides, provided with biological samples and with an electronically readable identification code, inside a tray divided, by means of separation structures, into multiple compartments, each compartment being adapted to contain one of the slides in an orderly manner. The loading machine includes: a supporting frame structure for resting on a work surface; a linear feeder of the tray with respect to the frame structure; an inserter of the slides into the tray in an orderly and sequential manner; a reader of the identification code provided on each of the slides; and a control unit. The inserter of the slides into the tray includes a unit to temporarily retain each slide and to release it, in coordination with the reader and linear feeder of the tray, into one of the compartments making use of gravity.

A scanning stage with opposing edges to secure a slide during scanning and guide the slide during unloading. In an embodiment, the system includes a reference edge with a surface facing a first edge of the slide and an opposing edge with a surface facing a second edge of the slide. The opposing edge is controlled by a processor to engage the second edge of the slide and press the first edge of the slide against the reference edge surface. The opposing edge surface is parallel to a side of a slide rack slot into which the slide will be inserted during unloading. The system also includes an assembly having a pull bar configured to pull the glass slide from the scanning stage into the slide rack slot while the first edge of the slide is simultaneously being pressed against the reference edge surface by the opposing edge surface.

Graphical user interface for managing a workflow of a slide scanning system. In an embodiment, the graphical user interface comprises a graphical representation of a carousel used by the scanning system. The graphical representation of the carousel comprises a graphical representation of each of a plurality of rack slots, configured to receive slide racks. The graphical representation of the carousel indicates a position of the carousel, and the graphical representation of each of the plurality of rack slots indicates a status of the represented rack slot and/or a slide rack within the represented rack slot.

A slide imaging apparatus includes: at least one imaging device configured to generate an image of a sample mounted on a slide, wherein the imaging device comprises an operating button; a storage device loadable with a plurality of slides and configured to store the slides; and a supply device configured to supply the slides from the storage device to the imaging device, wherein the supply device is configured to press the operating button.

Methods and systems for automated slide handling for imaging applications are described herein. In certain aspects, an automated slide handler may be operatively coupled to a slide hotel and/or one or more imaging systems described herein. The automated slide handler may be a robotic arm with up to 6 degrees of freedom. Automated slide handling may include sample preparation, such as sectioning and staining. Suitable imaging systems include a fluorescence microscope or an imaging mass cytometer. Methods and systems disclosed herein enable high throughput profiling of tissue sections.

A sample processing system and method, and a control system and a cell image analysis device. A smear preparation device prepares a sample smear, the cell image analysis device performs imaging and analysis on the sample smear, and the sample smear is placed in a first smear storage device. After the sample smear is placed in the first smear storage device, the first smear storage device placed with the sample smear is conveyed by a conveyer from the smear preparation device to the cell image analysis device, and the first smear storage device is conveyed by the conveyer from the cell image analysis device to the smear preparation device, so that automatic cycle conveying of the first smear storage device between the smear preparation device and the cell image analysis device is achieved by the conveyer, and unnecessary human-machine interaction operations are reduced, thereby reducing workload of a user.

A method for scanning object carriers using at least two microscope slide scanners includes a) loading a feed unit for microscope slides with a plurality of microscope slides, each of which is part of one of a plurality of sample series, b) transferring one microscope slide from the feed unit to every microscope slide scanner not loaded with a microscope slide, c) carrying out a scanning process for each loaded microscope slide scanner, d) transferring each scanned microscope slide from the microscope slide scanner to an intermediate storage rack, e) providing a data set for every scanning process for analysis, and f) transferring all microscope slides of a sample series from the intermediate storage rack to a final storage rack.