The invention is that of systems of methods for preserving vital assets such as human organs in transit. An exemplary system may include a central software application and processor for storing vital asset identifying information in a database and displaying real-time transit information in relation to the asset to authenticated users. Application programming interfaces are provided to allow authenticated users to monitor location and environmental data transmitted from the proximity of the asset to the central software application for processing and display on graphical user interfaces. An exemplary system enables methods of reallocating freight from a first to a second transportation asset to avoid delays and prolonged exposures to adverse environmental conditions. In certain embodiments, unmanned aerial systems may be deployed to intervene in the transit channel and overcome such delays or exposures. In preferred embodiments, historical data is collected and analyzed to help predict human organ transplant outcomes.

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 portable apparatus and method for transport and incubation of a medical sample in a blood culture flask includes a sealable container having a thermally insulated compartment for receiving the blood culture flask and a heater for heating the medical sample to a temperature suitable for pre-culturing of the sample. An agitator is provided for agitating the sample in the blood culture flask.

A system for the hypothermic transport of biological samples, such as tissues, organs, or body fluids. The system includes an antimicrobial treatment mechanism to inactivate microbes flushed from the biological sample by preservation fluid flowed therethrough. 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 while simultaneously treating microbial infections to prevent transmission between a donor and a recipient.

A system for the hypothermic transport of biological samples, such as tissues, organs, or body fluids. The system includes support systems to permit arrangement of cooling media around a biological sample without potentially damaging direct contact between the cooling media and the biological sample. Systems and methods disclosed herein also include specific configurations, types, and performance characteristics of cooling media such as phase change materials to allow for extended hypothermic storage and transport.

Methods for cooling organs. The methods include using a layered organ support surface with a temperature sensor. The organ support surface can have a cushion layer, a core layer, and an insulating layer. The insulating layer can insulate the cooling media from the organ.

Dosage units consist of an autologous cell therapy product composed of fibroblasts grown for each individual to be treated for augmentation or regeneration of vocal cords. The suspension of autologous fibroblasts, grown from a biopsy of each individual's own buccal mucosa or skin using current good manufacturing practices (CGMP) and standard tissue culture procedures, is supplied in vials containing cryopreserved fibroblasts or precursors thereof, having a purity of at least 98% fibroblasts and a viability of at least 85%, for administration of from one to six mL, preferably two mL administered three times approximately three to six weeks apart, of cells at a concentration of from 1.0-2.010.sup.7 cells/mL.

The disclosure relates to devices, solutions and methods for collecting and processing samples of bodily fluids containing cells (as well as embodiments for the collection, and processing and/or analysis of other fluids including toxic and/or hazardous substances/fluids). In addition, the disclosure relates generally to function genomic studies and to the isolation and preservation of cells from saliva and other bodily fluids (e.g., urine), for cellular analysis. With respect to devices for collection of bodily fluids, some embodiments include two mating bodies, a cap and a tube (for example), where, in some embodiments, the cap includes a closed interior space for holding a sample preservative solution and mates with the tube to constitute the (closed) sample collection device. Upon mating, the preservation solution flows into the closed interior space to preserve cells in the bodily fluid. The tube is configured to receive a donor sample of bodily fluid (e.g., saliva, urine), which can then be subjected to processing to extract a plurality of cells. The plurality of cells can be further processed to isolate one and/or another cell type therefrom. The plurality of cells, as well as the isolated cell type(s), can be analyzed for functional genomic and epigenetic studies, as well as biomarker discovery.

A system and method facilitates transfers of specimen containers (e.g., vials with caps) between storage cassettes and carrier cassettes. The storage cassettes are designed to be stored in cryogenic refrigerators while the carrier cassettes are designed to be temporarily stored in a portable carrier. A workstation includes a well and removable buckets positioned in the well. The buckets are sized to hold the storage cassettes and carrier cassettes. One or more arrays of antennas underlie the well to allow interrogation of wireless transponders carried by the specimen containers. Improved storage cassettes and carrier cassettes are also described.

A system and method facilitates transfers of specimen containers (e.g., vials with caps) between storage cassettes and carrier cassettes. The storage cassettes are designed to be stored in cryogenic refrigerators while the carrier cassettes are designed to be temporarily stored in a portable carrier. A workstation includes a well and removable buckets positioned in the well. The buckets are sized to hold the storage cassettes and carrier cassettes. One or more arrays of antennas underlie the well to allow interrogation of wireless transponders carried by the specimen containers. Improved storage cassettes and carrier cassettes are also described.