Embodiments of methods, systems, and apparatuses for lyophilizing, storing, and transfusing materials are described. In embodiments, the materials may include whole blood or a component of whole blood such as plasma.

Embodiments of methods, systems, and apparatuses for lyophilizing, storing, and transfusing materials are described. In embodiments, the materials may include whole blood or a component of whole blood such as plasma.

A device is provided for storing elements, each element including a first wireless communication unit. The device includes at least two drawer units each including: a drawer including a bottom defining at least one location for receiving an element; for each location, at least one second wireless communication unit including an antenna having a radiation-zone field, each antenna having a first state in which the antenna is activated and a second state in which the antenna is deactivated; and a data-processing unit able to control the activation and deactivation of the antenna of each second communication unit according to a control law.

A device is provided for storing elements, each element including a first wireless communication unit. The device includes at least two drawer units each including: a drawer including a bottom defining at least one location for receiving an element; for each location, at least one second wireless communication unit including an antenna having a radiation-zone field, each antenna having a first state in which the antenna is activated and a second state in which the antenna is deactivated; and a data-processing unit able to control the activation and deactivation of the antenna of each second communication unit according to a control law.

A Thermally Isolated Blood Carrier Tray includes a main panel having a plurality of thermally isolated compartments attached thereto. The thermally isolated compartments are arranged in two separate matrices having a plurality of column and rows. Each thermally isolated compartment is thermally isolated from an adjacent thermally isolated compartment. Each thermally isolated compartment maintains its own heat transfer rate without being affected by an adjacent thermally isolated compartments heat transfer rate. The placement of several different storage units having different temperatures into the Thermally Isolated Blood Carrier Tray does not affect the heat transfer rate of any one storage unit in a thermally isolated compartment. The Thermally Isolated Blood Carrier Tray provides a steady and even heat transfer from the storage unit to bring the storage units to an appropriate temperature for storage or transportation.

Systems and methods are provided for deriving a platelet product from a plurality of buffy coats. A plurality of buffy coats are separately collected, for example, using a conventional floor centrifuge. Plasma and/or a platelet additive solution may be added to the buffy coats. The buffy coats are pooled into a container and conveyed into a centrifuge or are sequentially conveyed into the centrifuge without being pooled, where they are continuously processed to separate platelets from the other cellular blood components. The separated platelets are conveyed out of the centrifuge as a platelet product, which may be passed through a leukocyte removal filter to reduce the white blood cell content of the platelet product. By continuously separating the buffy coats, fewer buffy coats are required to produce a single-dose platelet product, while also allowing for the derivation and collection of a plurality of single-dose platelet products.

A Thermally Isolated Blood Carrier Tray includes a main panel having a plurality of thermally isolated compartments attached thereto. The thermally isolated compartments are arranged in two separate matrices having a plurality of column and rows. Each thermally isolated compartment is thermally isolated from an adjacent thermally isolated compartment. Each thermally isolated compartment maintains its own heat transfer rate without being affected by an adjacent thermally isolated compartments heat transfer rate. The placement of several different storage units having different temperatures into the Thermally Isolated Blood Carrier Tray does not affect the heat transfer rate of any one storage unit in a thermally isolated compartment. The Thermally Isolated Blood Carrier Tray provides a steady and even heat transfer from the storage unit to bring the storage units to an appropriate temperature for storage or transportation.

Disclosed is a multiple bag system for fractionating blood, the system including a fluid collecting bag including at least one outlet port; at least first and second sampling bags, each including at least one inlet port and at least one outlet port; and a fluid transfer unit to transfer fluid from the collecting bag to the sampling bags. The fluid transfer unit includes an acoustic sorter. Also disclosed is a method for fractionating blood into blood products.

Disclosed is a method for managing at least one container containing a biological product, including the following steps: providing at least one container provided with a label, the label being a wireless communication chip capable of communicating according to a UHF mode and according to a HF mode, the chip being capable of transmitting or receiving a signal having a frequency of between 300 MHz and 3000 MHz in the UHF mode and having a frequency of between 3 MHz and 30 MHz in the HF mode, the label further including a memory; and reading at least one piece of information included in the memory, by a reader, the chip communicating with the reader according to the UHF mode or the HF mode.

Provided is a compact lightweight transport box in which the internal temperature distribution is minimized and accurate temperature regulation can be performed. The transport box includes an insulating container, an internal heat conducting container mounted in the insulating container, and an insulating cover body with a cover internal side heat conducting plate exposed on an inner surface facing the opening part of the internal heat conducting container, in which, with the opening part of the insulating container closed by the insulating cover body, the cover internal side heat conducting plate is near an opening end of the internal heat conducting container.