The present invention provides improved methods, facilities and systems for parallel processing of biological cellular samples in an efficient and scalable manner. The invention enables parallel processing of biological cellular samples, such as patient samples, in a space and time efficient fashion. The methods, facilities and systems of the invention find particular utility in processing patient samples for use in cell therapy.

A laboratory system for analyzing biological samples is presented. The laboratory system comprises a plurality of laboratory instruments configured to receive and identify biological samples and to query a laboratory control unit for a processing order indicative of processing steps to be carried out on the biological sample. The laboratory control unit is configured to validate sequence of queries from the plurality of laboratory instruments against a valid query sequence pattern.

The disclosure relates to a sampling system for processing a liquid sample, including a retrieving module configured to be fluidically connected to a liquid-source and configured to retrieve a liquid sample from the liquid-source, a filling module configured to fill the retrieved liquid sample into a sampling container, a storing module configured to store the sampling container filled with the liquid sample, and a disposal module configured to discard the liquid sample.

An automatic analyzer with high processing capacity is capable of immediately measuring an emergency specimen rack. The automatic analyzer includes a conveying line for conveying a specimen rack, and an analysis unit which has a dispensing line in which a plurality of specimen racks are arranged for waiting until sample dispensing, and a sampling area for dispensing the sample to the analysis unit. A rack save area is provided in the dispensing line and at a position adjacent to the upstream side of the sampling area. When a specimen rack exists in the sampling area at the time of measuring an emergency specimen rack, a controller moves the specimen rack to the save area and positions the emergency specimen rack to be moved from a downstream side of the sampling area to the sampling area.

The present patent of invention relates to a reader device for biological samples used in the field of remote laboratory tests (TLR), for clinical diagnostic purposes, based on an optimized design constituted by a cowling (C) with inlet port (OE) and with switch (I); by a holding support (SS) containing a mirror (ES), two batteries (BT), two reading illumination arrays (BIL), operational status illumination arrays (BIS) and an elevator support (SE); by an elevator (EL); by an electronics board (PE) with energy loading circuit (PE-1), with supply circuit (PE-2), with processor (PE-3), with Bluetooth device (PE-4) and with position sensor (PE-5); and by a base (BA) with software that reads various types of biological samples, the present invention providing the advantages of: ease of use, optimized operating flows, ease of training, modularity, compactness, reduced size, portability, lightness of weight, ergonomic design, used-friendliness, enhanced practically and low cost

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.

The present invention describes an integrated incubator and image capture module that regulates the incubator atmosphere and obtains high-resolution digital images of sample specimens. The incubator has a cabinet type enclosure that enables the provision of a controlled environment to the contents of the incubator by having at least three ports on one face of the cabinet for the passage of sample containers. Additionally, an image capture module is located immediately adjacent to the incubator. In this regard, using at least three separate access/egress points for the sample containers streamlines operation of the system and enhances preservation of the incubator environment. Furthermore, locating the image capture module directly adjacent to the incubator reduces the amount of time a sample container is exposed to the external environment, thereby reducing the extent to which samples are exposed to potential contaminants and reducing the exchange of the lab and ambient atmospheres.

A system for automation of sample preparation is disclosed. The system for automation includes a fixture configured to hold a sample and a reader system configured for receiving information pertinent to the sample. In various implementations, the system includes a cutting system configured for removing a portion of the sample. In various implementations, the system includes a cutting system configured for cutting the sample into at least two portions. In various implementations, the system further includes a first bin for collecting a first portion of the at least two portions of the sample. In various implementations, the system also includes a second bin for collecting a second portion of the at least two portions of the sample. In various implementations, the plurality of specimens are arranged linearly along one direction or arranged laterally in a two-dimensional array.

Features are disclosed for managing slides of tissue sample bocks to be mapped to staining instruments by a slide management apparatus. Each staining instrument may be associated with particular features or characteristics identifying capabilities of the staining instrument. The slide management apparatus can generate groups of slides based on the features or characteristics of each staining instrument. Each group of slides may share the same or similar characteristics. Further, the slide management apparatus can dynamically map the groups of slides to the staining instruments. The slide management apparatus may map the groups of slides based on a staining completion time. The slide management apparatus can generate a recommendation for a user based on mapping the groups of slides. For example, the recommendation may include a recommendation to place a first group of slides in a first staining instrument for staining.

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.