An object of the present invention is to provide a container for cryopreservation and transportation which is excellent in maintainability and can appropriately control the temperature of an object to be frozen. The present invention provides a container for cryopreservation and transportation used to transport an object to be frozen, including: a thermal insulation container having an upper opening; a thermal insulation lid which closes the upper opening of the thermal insulation container; and a cooling unit which is held in the thermal insulation container while absorbing liquid nitrogen, wherein a housing space for accommodating a storage tool for storing the object to be frozen is provided inside the thermal insulation container, and the cooling unit is detachable through the upper opening of the thermal insulation container while the storage tool located in the housing space is housed in the thermal insulation container.

Methods, devices, and kits are provided for use in washing or cryopreserving live cells or tissue, such as fat graft tissue.

A device for transporting objects such as a graft is configured to efficiently establish a liquid-tight state with a simple operation. The device is to be used in a state of being detachably attached to a container for storing a graft, the device including: a lid member for sealing the container; and an annular member for forming a first space by being interposed between the lid member and the container, wherein a second space is formed between the lid member and an inside surface of the container.

A vessel is provided for cryopreservation by vitrification for use in the cryopreservation by vitrification of cells or embryos. The cells or embryos are retained by a retaining part of the vessel and has recesses on the retaining part to store the cells or embryos therein. The vessel for cryopreservation by vitrification in a liquid cryogen has holes in the walls which make up the recesses which do not allow the cells or embryos to pass through the walls, but which do allow vitrification solution to pass therethrough. A kit is also provided which includes the vessel and a tube for storing the vessel. A method for cryopreservation by vitrification in a liquid cryogen is also provided.

The present invention relates to a shielding device to reduce the impact of radiation, that contains a container (10) with a receptacle (14) and a functional filling (20) placed into the receptacle (14) of the container (10), where the functional filling (20) is composed of a collecting component (21) that contains a mixture of inorganic substances and a utilizing component (22) that contains a mixture of organic components.

Metastable state spore incubation mixing systems are described. An example system includes a spore container to store spores, a nutrient container, an arrangement of valves and tubes, a reciprocating pump, a mixing tube, and a holding tank. In a drawing phase of the system, a controller can control the reciprocating pump to draw a ratioed volume of the spores, the nutrients, and water through the valves and tubes. During an expelling phase of the system, the controller can control flow control valves to direct the spores, nutrients, and water through the mixing tube and into the holding tank. The controller can also direct a heater to heat the mixture in the holding tank to a predetermined temperature. Once the mixture reaches the temperature, the controller can also direct the system through a number of other phases of operation, including cooling and purging phases.

A system for the hypothermic transport of biological samples, such as tissues, organs, or body fluids. The system includes a self-purging preservation apparatus to suspend a sample in preservation fluid and perfuse a tissue with preservation fluid. The self-purging preservation apparatus is placed in an insulated transport container having a cooling medium. When assembled, the system allows for transport of biological samples for extended periods of time at a stable temperature.

A specimen holding and positioning apparatus operable to substantially non-movably maintain a specimen (e.g., an excised tissue specimen) in a fixed or stable orientation with respect to the apparatus during imaging operations (e.g., x-ray imaging), transport (e.g., from a surgery room to a pathologist's laboratory), and the like for use in facilitating accurate detection and diagnosis of cancers and/or other abnormalities of the specimen.

A system and method for preservation, storage and transport of biological materials by the use of at least one deformable container configured with at least one inlet at one end, an outer surface greater than 80% of the total surface of the cavities of the support and a width and length sufficient for it to be placed in contact with all the heat transfer plates of the support. The support has at least two cavities delimited by the heat transfer plates, with temperature control device, side walls and at least one main front door. The system allows improvement of the heat transfer necessary for freezing and thawing large volumes of solutions containing biological materials. It also allows to considerably accelerate the heat transfer, as well as the reproducibility and scalability of the freezing and thawing process while keeping the system very compact.

The current disclosure provides a method for the creation of a high-density cryopreserved cell bank using perfusion culture techniques and non-centrifugal concentration of cells. Methods of production using this high-density cryopreserved cell bank are also provided.