Systems and devices with enhanced stability to kinetic impact for the containment of cryogenically preserved material. A device comprising a vessel with increased surface to volume ratio when compared to cylindrical vessels of like capacity, and further comprising a material that remains resistant to shock and impact at cryogenic temperatures while providing a continuous barrier of a single material surrounding the vessel contents. The device further comprising a design that may be readily modified to include internalized sensors, enhanced interfacing to external instruments, provide optimized thaw rate, and post-thawing sample processing capabilities.

Systems and methods of the invention generally relate to prolonging viability of bodily tissue, especially an organ such as a lung, by adjusting pressure as needed to maintain a constant pressure within the organ even during external pressure fluctuations due, for example, to transportation of the organ in an airplane. Gas passing into and out of the organ may be conditioned to prolong tissue viability.

Systems and methods of the invention generally relate to prolonging viability of bodily tissue, especially an organ such as a lung, by adjusting pressure as needed to maintain a constant pressure within the organ even during external pressure fluctuations due, for example, to transportation of the organ in an airplane. Gas passing into and out of the organ may be conditioned to prolong tissue viability.

A remote system for monitoring and controlling one or more devices for use in the cryogenic processing of a sample is provided. A remote server (130) is provided, capable of transmitting freezing profile data to one or more freezers (101, . . . , 10n), transmitting transportation profile data to one or more transportation devices, and transmitting thawing profile data to one or more thawing devices. The remote server is also capable of receiving detected data from the one or more freezers relating to the freezing of a sample in accordance with the freezing profile data, receiving detected data from the one or more transportation devices relating to the transportation of a sample in accordance with the transportation profile data, and receiving detected data from the one or more thawing machines relating to the thawing of a sample in accordance with the thawing profile data.

A remote system for monitoring and controlling one or more devices for use in the cryogenic processing of a sample is provided. A remote server (130) is provided, capable of transmitting freezing profile data to one or more freezers (101, . . . , 10n), transmitting transportation profile data to one or more transportation devices, and transmitting thawing profile data to one or more thawing devices. The remote server is also capable of receiving detected data from the one or more freezers relating to the freezing of a sample in accordance with the freezing profile data, receiving detected data from the one or more transportation devices relating to the transportation of a sample in accordance with the transportation profile data, and receiving detected data from the one or more thawing machines relating to the thawing of a sample in accordance with the thawing profile data.

A method of preserving a donor heart, comprising perfusing the donor heart with oxygenated blood-based perfusate, wherein the donor heart is predominantly kept in non-beating state.

An apparatus includes a flexible container and a port. The container includes a first layer coupled to a second layer to define a storage volume within which a tissue specimen can be contained. The first layer has a first stiffness and the second layer has a second stiffness. An edge of the first layer is spaced apart from an edge of the second layer to define an opening into the storage volume. The edges of the first and second layer form a peelable seal that hermetically seals the storage volume such that the first layer can be peeled away from the second layer to expose the storage volume. The port is coupled to the flexible container and allows fluid communication between the storage volume and an external volume.

An apparatus includes a flexible container and a port. The container includes a first layer coupled to a second layer to define a storage volume within which a tissue specimen can be contained. The first layer has a first stiffness and the second layer has a second stiffness. An edge of the first layer is spaced apart from an edge of the second layer to define an opening into the storage volume. The edges of the first and second layer form a peelable seal that hermetically seals the storage volume such that the first layer can be peeled away from the second layer to expose the storage volume. The port is coupled to the flexible container and allows fluid communication between the storage volume and an external volume.

Embodiments for a portable and compact centrifugation and thermal management system capable of separating and transporting biological samples while maintaining sample quality for periods of shipment time are described. A compact, automatic centrifuge holding exactly one sample tube is inside an insulating and thermally managed container suitable for standard shipping. A rotor to retain a sample tube is pre-balanced. An electronic controller starts, times and stops centrifugation automatically, responsive to placement of a lid. Thermal management may comprise a phase change material. Embodiments are free of user controls. Embodiments are free of the need for external power or external control.

Embodiments for a portable and compact centrifugation and thermal management system capable of separating and transporting biological samples while maintaining sample quality for periods of shipment time are described. A compact, automatic centrifuge holding exactly one sample tube is inside an insulating and thermally managed container suitable for standard shipping. A rotor to retain a sample tube is pre-balanced. An electronic controller starts, times and stops centrifugation automatically, responsive to placement of a lid. Thermal management may comprise a phase change material. Embodiments are free of user controls. Embodiments are free of the need for external power or external control.