Tissue sample management systems include a central network, a medical professional system, and a pathology lab system for processing a tissue sample in a matrix having a sectionable code. At least the pathology lab system includes at least one imaging device, and the central network is configured to process images from the at least one imaging device to identify and record at least the sectionable code of the matrix. Methods for tissue sample processing include providing a matrix having a sectionable code and measurement marks, the matrix for receiving a tissue sample, and identifying the sectionable code from an image taken of the tissue sample in the matrix. Tissue sample-receiving matrices include a sectionable alphanumeric code or bar code, a tissue sample receptacle, and measurement marks formed along a sidewall thereof. The matrices include one or more proteins and one or more lipids.

A device for processing and cataloging of a sample, in a container having a label with identifying data, has a frame; a plurality of cameras mounted to the frame; and a controller system coupled to the cameras, the controller system including a controller and a non-transitory memory storing instructions, which, when executed by the controller, cause carrying out of computer processes that produce a catalog record output characterizing the sample, such record also including the identifying data.

A method of reading machine-readable labels on sample receptacles held by a sample rack. In the method, an absolute position of the sample rack is measured as the sample rack moves between first and second positions in a housing. During movement between the first and second positions, an image is acquired of a machine-readable label associated with each sample receptacle held by the sample rack. The image of each machine-readable label is thereafter decoded.

A user interface used with a medical testing machine provides improved recall and display of the outcomes of tests performed by the machine. Test outcomes and other information are stored in mass storage directly accessible by the medical testing machine. In one aspect, outcomes of tests relating to a particular patient may be recalled. The system may be especially useful for tests that may be performed multiple times for a particular patient over a period of time, for example testing for HbA1c hemoglobin levels in diabetes patients. The user interface presents a set of screens that allow the display of data according to various filters, and so as to provide detailed information about tests performed by the machine.

A high throughput system and method for analyzing the effects of a plurality of agents on planaria is disclosed. Multiple test zones are provided, where each test zone contains at least a portion of one planarian. The planaria in each test zone are then exposed to at least one agent, the test zones are sealed, and at various times, the test zones are moved automatically between a storage location and at least one assay station. At each assay station, the test zones are exposed to a set of conditions, and an image or video of the planaria in the test zones are captured. Automated image or video analysis is used to are evaluate and determine whether the agent has an effect.

A device for processing and cataloging of a sample, in a container having a label with identifying data, has a frame; a plurality of cameras mounted to the frame; and a controller system coupled to the cameras, the controller system including a controller and a non-transitory memory storing instructions, which, when executed by the controller, cause carrying out of computer processes that produce a catalog record output characterizing the sample, such record also including the identifying data.

A sample identification system for an automated sampling and dispensing device is described. In an example implementation, the sample identification system includes a sample probe configured to contact a sample positioned within a sample vessel. Further, the sample identification system includes an identifier capture device configured to measure a sample identifier associated with the sample vessel and generate a data signal in response thereto, where the data signal corresponds to an identity of the at least one sample. During operation, the identifier capture device scans a sample holder, a sample vessel, or a table top of the automated sampling and dispensing device to measure the sample identifier and to generate the data signal in response thereto.

The present invention relates to imaging microscope slides. In order to further improve a workflow for slide scanning, a system (10) for imaging microscope slides is provided that comprises a store area unit (12), a code readout unit (14), and a data interface unit (16). The store area unit is configured to receive a plurality of slides, each slide having a code comprising slide related information. The code readout unit is configured to detect the respective codes of a stored plurality of slides. The data interface unit is configured to provide the detected codes for a generation of a code inventory and to receive a determined scan order based on the code inventory.

A method of reading machine-readable labels on sample receptacles. In the method, a sample rack is moved between a first position and a second position withing a housing, where the sample rack supports a plurality of sample receptacles, and each sample receptacle has a machine-readable label. An absolute position of the sample rack is measured as the sample rack moves between the first and second positions. An image of the machine-readable label associated with each sample receptacle is acquired as the sample rack moves between the first and second positions. Finally, the acquired image of each machine-readable label is decoded.

A sample-containing device configured to be placed into a sample processing instrument for performing a process on a sample contained in the device includes redundant identification features, such as machine-readable tags. A first machine-readable information tag is read before the device is placed in the instrument, and a second machine-readable information tag is read after the device is in the instrument. Information read from the two tags is compared to determine if there is proper correspondence between the information read from the tags to ensure that the correct sample processing device was placed in the instrument.