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.

Described are flexible vessels that are useful for containing a liquid and freezing the liquid, and a flexible resistive heating element that is adapted to heat the frozen liquid to cause the frozen liquid to melt.

This disclosure relates to a method and system for fast freezing of a biological product (such as blood plasma) contained in an individual bag or a plurality of bags. This disclosure relates to a method and a-system for freezing plasma in an individual bag or a plurality of bags, favoring bottom-up ice-growth, by implementing a differential air flow on top and bottom surfaces of a horizontally placed bag or bags filled with plasma. This disclosure relates to a method and a differential air flow system for freezing plasma, wherein the heat transfer coefficient on a bottom of a bag is at least 10 times larger than at a top. This disclosure relates to a differential air flow system and method for freezing plasma, wherein the differential air flow on top and bottom surfaces of a plasma bag is imposed by at least one fan or blower.

This disclosure relates to a method and system for fast freezing of a biological product (such as blood plasma) contained in an individual bag or a plurality of bags. This disclosure relates to a method and a-system for freezing plasma in an individual bag or a plurality of bags, favoring bottom-up ice-growth, by implementing a differential air flow on top and bottom surfaces of a horizontally placed bag or bags filled with plasma. This disclosure relates to a method and a differential air flow system for freezing plasma, wherein the heat transfer coefficient on a bottom of a bag is at least 10 times larger than at a top. This disclosure relates to a differential air flow system and method for freezing plasma, wherein the differential air flow on top and bottom surfaces of a plasma bag is imposed by at least one fan or blower.

Methods, systems, and compositions are provided for extracting bone marrow cells from bone obtained from deceased donors, for preparing the bone marrow for cryopreservation, and for obtaining desired cells from cryopreserved and fresh bone marrow. In some embodiments, the methods provide cryopreserved compositions having increased viability of bone marrow cells.

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.

The invention is directed to an energy efficient thermoelectric heat pump assembly. The thermoelectric heat pump assembly preferably comprises two to nine thermoelectric unit layers capable of active use of the Peltier effect; and at least one capacitance spacer block suitable for storing heat and providing a delayed thermal reaction time of the assembly. The capacitance spacer block is thermally connected between the thermoelectric unit layers. The present invention further relates to a thermoelectric transport and storage devices for transporting or storing temperature sensitive goods, for example, vaccines, chemicals, biologicals, and other temperature sensitive goods. Preferably the transport or storage devices are configured and provide on-board energy storage for sustaining, for multiple days, at a constant-temperature, with an acceptable temperature variation band.

A cryogenic cooling manifold and methods incorporating a cryogenic cooling manifold for managing the gas layer(s) above a liquid cryogen to control cooling temperature-time profiles and ice formation for microliter and smaller samples that are plunged through the gas and into the liquid cryogen.

An automated system and method of preparing oocytes, embryos, or blastocysts for cryopreservation. The method entails delivering two or more solutions into a container holding oocytes, embryos, or blastocysts, and controlling the flow of the solutions to gradually change the concentration of cryoprotectants and dehydrating agents in the container to minimize shock to the oocytes, embryos or blastocysts.

An automated system and method of preparing oocytes, embryos, or blastocysts for cryopreservation. The method entails delivering two or more solutions into a container holding oocytes, embryos, or blastocysts, and controlling the flow of the solutions to gradually change the concentration of cryoprotectants and dehydrating agents in the container to minimize shock to the oocytes, embryos or blastocysts.