The present invention relates to a system which permits securing an electronic label on a test tube. In particular, it refers to an Internet of Things (IoT) based platform for real-time remote sensing and monitoring of specimen transportation and banking. The technology is based on an interconnected smart collecting tubes and transportation box monitored with a remote digital interface, allowing real-time sample monitoring of key parameters such as sample identification, temperature, volume, geolocalization, sealing and bio-banking.

The present invention relates to a system which permits securing an electronic label on a test tube. In particular, it refers to an Internet of Things (IoT) based platform for real-time remote sensing and monitoring of specimen transportation and banking. The technology is based on an interconnected smart collecting tubes and transportation box monitored with a remote digital interface, allowing real-time sample monitoring of key parameters such as sample identification, temperature, volume, geolocalization, sealing and bio-banking.

Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

An analysis cartridge includes a first cover, a second cover, a plurality of containers, a plurality of fluid tunnels and a rotary valve. The second cover has two opposite surfaces, a plurality of first through holes and a second through hole individually penetrate through the two opposite surfaces, and the first cover is attached to the second cover. The plurality of containers are disposed between the first cover and the second cover, with each of the containers being aligned to and filled in the first through holes. The plurality of the fluid tunnels are disposed on the first cover, and each of which is individually connected with a first pipette. The rotary valve is rotatably disposed between the first cover and the second cover to correspond to the second through hole, and a flow channel disposed on the rotary valve is connected with the containers individually.

A holding structure for holding a plurality of containers for pharmaceutical, medical or cosmetic purposes includes a carrier having openings or receptacles for accommodating the containers. Holding devices for holding the containers are provided at the openings or receptacles. The holding devices can selectively assume two different stable positions, namely a first stable position in which the containers can be inserted without friction into the openings or receptacles and a second stable position in which the containers are held in the respective opening or receptacle by frictional engagement or by positive locking. The containers can be reliably inserted into the openings or receptacles without material abrasion. In the open insertion position of the holding devices, a large number of containers can be inserted concurrently into the openings or receptacles without high forces acting on the holding structure.

A holding structure for holding a plurality of containers for pharmaceutical, medical or cosmetic purposes includes a carrier having openings or receptacles for accommodating the containers. Holding devices for holding the containers are provided at the openings or receptacles. The holding devices can selectively assume two different stable positions, namely a first stable position in which the containers can be inserted without friction into the openings or receptacles and a second stable position in which the containers are held in the respective opening or receptacle by frictional engagement or by positive locking. The containers can be reliably inserted into the openings or receptacles without material abrasion. In the open insertion position of the holding devices, a large number of containers can be inserted concurrently into the openings or receptacles without high forces acting on the holding structure.

An apparatus for temperature-controlling and thawing a temperature-controlled material which is arranged in at least one rigid container, including an openable housing containing a storage chamber for receiving the at least one container, and including a heating device containing a flat heating element which is operatively connected to the at least one container. A storage mat for receiving the at least one container is arranged between the flat heating element and the at least one container.

A container for receiving vessels for use in an automated analyzer is presented. The container comprises a wall assembly including a first wall and a second wall. The wall assembly forms a receptacle for receiving a vessel having one or more covers or lids. At least one of the first and second walls moves to provide a first open configuration for receiving the vessel and a second closed configuration. The container further comprises an actuator configured to translate the vessel from a first position after being received in the container to a second position and the wall assembly in the second closed configuration is positioned so that at least one engaging element attached to the wall assembly engages with the covers or lids of the vessel to open the covers or lids while the vessel is being translated by the actuator from the first position to the second position.

The present disclosure relates to a laboratory sample container carrier handling apparatus comprising a revolving device, being adapted to move a sample container carrier supplied to the revolving device along a circular path P, and wherein the circular path P has at least one ascending ramp. The present disclosure relates further to a laboratory sample distribution system comprising such a laboratory sample container carrier handling apparatus.

The present disclosure relates to a laboratory sample container carrier handling apparatus comprising a revolving device, being adapted to move a sample container carrier supplied to the revolving device along a circular path P, and wherein the circular path P has at least one ascending ramp. The present disclosure relates further to a laboratory sample distribution system comprising such a laboratory sample container carrier handling apparatus.