Example networked material testing systems include: a database system storing a shared database, the shared database storing a material test procedure and material test result data; a first material test system communicatively coupled to the database system and configured to perform a first type of material test; and a second material test system communicatively coupled to the database system and configured to perform the first type of material test; wherein the database system comprises a computing device configured to execute machine readable instructions which cause the computing device to: transmit a first test program to the first material test system for performance of the first type of material test on a first specimen according to the first test program; store, in the shared database, first test result data received from the first material test system based on execution of the first test program; transmit a second test program to the second material test system for performance of the first type of material test on a second specimen according to the second test program; store, in the shared database, second test result data received from the first material test system or the second material test system based on execution of the second test program; and generate one or more test reports based on the first test program, the first material test system that performed the first test program, the second test program, and the second material test system that performed the second test program.

A server stores a set of laboratory applications to process batches of samples. The server receives, from a first lab administrator, a selection of a subset of the laboratory applications to process the batches of samples and an admin configuration for a laboratory application in the subset. The server receives configuration(s) of batch(es) to be used for running at least a portion of the subset of laboratory applications configured according to the admin configuration. The server receives, from a first scientific device, a request to run a laboratory application form the first subset to process a batch. The server provides the laboratory application(s) that are capable of being executed using the first scientific device. The server receives, from the first scientific device, a selected laboratory application. The server transmits, to the first scientific device, a signal for executing a first part of the selected laboratory application.

The present disclosure also relates to systems and methods for quality control in histology systems. In some embodiments, a method is provided that includes receiving a tissue block comprising a tissue sample embedded in an embedding material, imaging the tissue block to create a first imaging data of the tissue sample in a tissue section on the tissue block, removing the tissue section from the tissue block, the tissue section comprising a part of the tissue sample, imaging the tissue section to create a second imaging data of the tissue sample in the tissue section, and comparing the first imaging data to the second imaging data to confirm correspondence in the tissue sample in the first imaging data and the second imaging data based on one or more quality control parameters.

A sample separation network includes a server node, a plurality of client nodes coupled with the server node, a plurality of sample separation devices coupled with the server node, wherein each of the sample separation devices includes device-specific control software configured for controlling specifically the respectively assigned sample separation device, wherein at least one of the server node and the client nodes includes generic control software configured for generically controlling sample separation devices in a non-device-specific way, and wherein at least one of the server node and the client nodes and the sample separation devices is configured for loading device-specific control software from a sample separation device to at least one of the server node and the client nodes upon connection of said sample separation device to the sample separation network.

The present disclosure also relates to systems and methods for quality control in histology systems. In some embodiments, a method is provided that includes receiving a tissue block comprising a tissue sample embedded in an embedding material, imaging the tissue block to create a first imaging data of the tissue sample in a tissue section on the tissue block, removing the tissue section from the tissue block, the tissue section comprising a part of the tissue sample, imaging the tissue section to create a second imaging data of the tissue sample in the tissue section, and comparing the first imaging data to the second imaging data to confirm correspondence in the tissue sample in the first imaging data and the second imaging data based on one or more quality control parameters.

A portable detector is disclosed for detecting certain analytes of interest, such as genetic material (e.g., nucleic acids). The detector includes a reading component for the detection of the analytes, and control circuitry for controlling operation of the reading component. Processing circuitry may be included to perform both primary analysis of acquired data, and where desired, secondary analysis. Where desired, some or all of the computationally intensive tasks may be off-loaded to enhance the portability and speed of the device. The device may incorporate various types of interface, technologies for reading and analysis, positioning system interfaces, and so forth. A number of exemplary use cases and methods are also disclosed.

The invention relates to a method for automatically blocking and/or unblocking a computer-supported medical device in a system, said system comprising the computer-supported medical device and a mobile terminal, wherein the mobile terminal comprises a first wireless communication device for wirelessly transmitting and receiving data and wherein mobile application software can be executed by means of the mobile terminal, wherein the medical device comprises a device computer and wherein the device computer comprises a second wireless communication device for wirelessly transmitting and receiving data, wherein driver software can be executed on the device computer, which can establish a wireless communication connection to the first communication device of the mobile terminal by means of the second communication device of the medical device, wherein the medical device is automatically shifted from a blocked state into an unblocked state, if the first communication device of the mobile terminal has established a wireless connection with the second communication device of the medical device and the signal strength of the signal of the first communication device of the mobile terminal, received by the second communication device of the medical device, exceeds a predetermined first threshold value and/or the medical device is automatically shifted from an unblocked state into a blocked state, if the first communication device of the mobile terminal has established a wireless connection with the second communication device of the medical device and the signal strength of the signal of the first communication device of the mobile terminal, received by the communication device of the medical device, falls below a predetermined second threshold value and/or if the wireless connection is interrupted for longer than a predetermined first time interval.

Provided herein are methods and systems of molecular profiling of diseases, such as cancer. In some embodiments, the molecular profiling can be used to identify treatments for a disease, such as treatments that were not initially identified as a treatment for the disease or not expected to be a treatment for a particular disease.

The present invention relates to methods, devices and systems for associating consumable data with an assay consumable used in a biological assay. Provided are assay systems and associated consumables, wherein the assay system adjusts one or more steps of an assay protocol based on consumable data specific for that consumable. Various types of consumable data are described, as well as methods of using such information in the conduct of an assay by an assay system.

A fluid mixture parameter determination (FMPD) system for analyzing a fluid mixture while moving includes a computing system and at least one material model that includes two or more model parameters for a plurality of material compositions stored in the memory. An ultrasonic sensor and a millimeter wave (MMW) sensor are each coupled to sense the fluid mixture and are coupled to the computing system. The ultrasonic sensor is for providing ultrasonic data to the computing system including a velocity of the fluid mixture or a volumetric flow, and a velocity of sound (VoS) through the fluid mixture. The MMW sensor is for providing MMW velocity data to the computing system. The computing system is for utilizing the material model together with the ultrasonic data and the MMW velocity data for identifying parameters including a plurality of components in the fluid mixture and a concentration for the plurality of components.