A method for preserving a tissue graft includes submerging the tissue graft in a solution containing one or more antimicrobial and/or stabilizing agents and storing the tissue graft in the solution for a period of time of at least 24 hours while the solution is in an unfrozen state. A tissue preservation system includes a solution containing one or more antimicrobial and/or stabilizing agents and a tissue graft in the solution.

A face is maintained for transplant by circulating perfusate in through vascular vessels of a face after removal from a donor until transplant. The method includes placing a transplantable face on a support that maintains its preexisting structural shape within a chamber. Circulation is maintained by pumping a perfusate from a reservoir through vascular vessels, collecting perfusate from the chamber and returning it to the reservoir for recirculation. Prior to recirculating the collected perfusate it is filtered and irradiated with radiant energy thereby inactivating pathogens. Prior to return the collected perfusate is oxygenated and purified by dialysis with the dialysate being recharged by being passed through an ion exchange medium.

This disclosure describes compositions and methods related to cryoprotection of biomaterial. Generally, the cryoprotective composition includes a cryoprotective agent and magnetic nanoparticles effective for thawing a cryopreserved specimen comprising biomaterial with minimal biomaterial damage. In some embodiments, the composition is effective for thawing a cryopreserved specimen having a minimum dimension of 0.1 mm. Generally, the method includes obtaining a biomaterial cryopreserved with a cryoprotective composition as summarized above, then subjecting the cryopreserved biomaterial to electromagnetic energy of an intensity sufficient to excite the magnetic nanoparticles and thaw the biomaterial.

This disclosure describes compositions and methods related to cryoprotection of biomaterial. Generally, the cryoprotective composition includes a cryoprotective agent and magnetic nanoparticles effective for thawing a cryopreserved specimen comprising biomaterial with minimal biomaterial damage. In some embodiments, the composition is effective for thawing a cryopreserved specimen having a minimum dimension of 0.1 mm. Generally, the method includes obtaining a biomaterial cryopreserved with a cryoprotective composition as summarized above, then subjecting the cryopreserved biomaterial to electromagnetic energy of an intensity sufficient to excite the magnetic nanoparticles and thaw the biomaterial.

Methods and compositions for the prevention or reduction of platelet transfusion associated complications are provided. The subject methods include modifying donor whole blood or platelets prior to transfusion to prevent or reduce alloimmune platelet refractoriness.

Methods and compositions for the prevention or reduction of platelet transfusion associated complications are provided. The subject methods include modifying donor whole blood or platelets prior to transfusion to prevent or reduce alloimmune platelet refractoriness.

Provided herein are systems, methods, and cryoprotective solutions for reversible cryopreservation of biological specimens, whole organs, and whole organisms. Exemplary methods include loading a cryoprotective agent into the biological specimen, cooling the biological specimen to a cryogenic temperature for preservation, storing the biological specimen at a preservation temperature state to preserve the biological specimen, rewarming the biological specimen by increasing a temperature of the biological specimen above the preservation temperature state, and unloading the cryoprotective agent from the biological specimen. The cooling is performed at a first rate to reduce ice formation, substantially homogeneously to reduce propensity for cracking of the preserved biological specimen, and at a first pressure to prevent or reduce ice expansion within the preserved biological specimen. The rewarming is performed at a second rate to reduce ice formation, substantially homogeneously to reduce propensity for cracking, and at a second pressure to prevent or reduce ice expansion.

Provided herein are systems, methods, and cryoprotective solutions for reversible cryopreservation of biological specimens, whole organs, and whole organisms. Exemplary methods include loading a cryoprotective agent into the biological specimen, cooling the biological specimen to a cryogenic temperature for preservation, storing the biological specimen at a preservation temperature state to preserve the biological specimen, rewarming the biological specimen by increasing a temperature of the biological specimen above the preservation temperature state, and unloading the cryoprotective agent from the biological specimen. The cooling is performed at a first rate to reduce ice formation, substantially homogeneously to reduce propensity for cracking of the preserved biological specimen, and at a first pressure to prevent or reduce ice expansion within the preserved biological specimen. The rewarming is performed at a second rate to reduce ice formation, substantially homogeneously to reduce propensity for cracking, and at a second pressure to prevent or reduce ice expansion.