A tissue cutting device that is especially suited for neurosurgical applications is disclosed and described, as well as alternative systems for tissue preservation and transport. The cutting device includes an outer cannula in which a reciprocating inner cannula is disposed. A tissue collector is also provided and is in fluid communication with the lumen of the inner cannula. A temperature control sleeve may be disposed around the tissue collector to control the temperature of the tissue samples. A preservation system may be supplied that is configured to deliver fluids to tissue samples in the tissue collector. A fluid supply sleeve may be disposed about the outer cannula and is selectively positionable along the length of the outer cannula.

An organ preservation system is provided. The organ preservation system is embodied in a sleeve adapted to maintain a pre-transplant organ at a temperature lower than ambient temperature through a plurality of bladders interconnected by a deformable mesh. With the organ in the sleeve, each vessel of the organ can pass through separate, deformable holes of the mesh, facilitating ease of identification of each vessel needed for the pending vascular anastomosis.

A platelet incubator usable as a lid for a refrigerated container includes a heating plate and a transparent cover. The heating plate has an aluminum top plate, an aluminum middle plate with an opening into which a silicon mat heater is placed, and a 5052 aluminum alloy bottom plate, with an aperture through which the wires providing electrical energy to the silicon mat heater are placed. The temperature is continuously monitored, and a log is kept for printout, allowing the platelet incubator to meet relevant compliance requirements. An alarm is activated if the temperature of the platelets exceeds twenty-three degrees Celsius, or falls under twenty-one degrees Celsius.

A tissue storage solution includes hypothermic storage compositions and methods. The hypothermic storage composition includes media containing Dulbecco's modified Eagle's medium (DMEM) and albumin. A method of hypothermically storing tissue includes storing such tissue in a storage medium including DMEM and albumin. A method for wound or defect treatment includes applying tissue, stored in a hypothermic storage medium containing DMEM and albumin, to the site of such wound or defect.

System and associated method for capturing, preserving, and transporting a bodily fluid, including a collection jar having a base body, a lid body, and a plunger, the plunger housing a preservative when in a first plunger position and permitting a release of the preservative into an internal cavity of the collection jar when in a second plunger position, where the plunger moves from the first plunger position to the second plunger position by pushing the plunger into the internal cavity, and a transportation packaging having an outer container, at least one vacuum insulated panel, at least one phase change material bottle, and at least one collection jar holding tray, where the phase change material bottle has an indented portion corresponding to an indented portion of the collection jar holding tray, where the collection jar is configured for placement in the at least one collection jar holding tray during transportation.

Provided is a loading tray assembly for housing a lyophilization container and a related system and method. The loading tray assembly includes a chassis including a contact void configured to facilitate direct contact between the attached lyophilization container and a lyophilizer shelf. The method includes securing a multi-part lyophilization container including a peelable seal on a lyophilization loading tray assembly, inputting a liquid into a non-breathable section of the lyophilization container, loading the tray assembly into a lyophilizer, freezing the liquid, applying heat energy and a vacuum, the vacuum causing an opening of the peelable seal and occluding the lyophilization container to isolate the frozen liquid.

The present invention provides a method and apparatus for tissue, such as an allograft, storage and preservation for extended periods of time at room temperature in a sterile tissue culture chamber. The invention further provides a process for maintaining the sterility of tissue using the apparatus as described.

Provided is a multi-part lyophilization container for lyophilizing a fluid, storing the lyophilizate, reconstituting the lyophilizate, and infusing the reconstituted lyophilizate into a patient, including a method of using same. The container includes a front surface, a back surface, a non-breathable section including a port region, a breathable section including a breathable membrane, and an occlusion zone encompassing a boundary between the non-breathable section and the breathable section. The non-breathable section is configured to accommodate any of a liquid, a solid, a gas or combination thereof. The breathable section is configured to accommodate only a gas. The method includes creating a temporary seal between the non-breathable section of the container and the breathable section, inputting a liquid into the non-breathable section, freezing the liquid, removing the temporary seal to allow vapor transport between the non-breathable section and the breathable section, and adding heat energy the frozen liquid under vacuum.

A support element for a plurality of packaging straws, the support element comprising a plate (31) and two flanges (37) rigidly connected to said plate (31) and comprising a fluted surface (53) having a plurality of similar grooves (36), each flange (37) comprising a central part as well as a first projecting part (42) and a second projecting part (43), each extending from one side of the central part, characterised in that the first projecting part comprises a bracket (42) having a bearing face and the second projecting part comprises another bracket (43) having another bearing face, said bearing face and said other bearing face being upwards facing and, in the direction of height, said bearing face being further from said plate (31) than said other bearing face. The assembly comprises the support element and a freezing rack (4).

A device for aseptic delivery of biological material from a vial includes a tubular barrel, a filter assembly, and a dispersion funnel assembly. The tubular barrel includes a receiving end to accept at least a portion of the vial within the tubular barrel, and a dispensing end opposite the receiving end. The filter assembly is fluidly connected to the dispensing end of the tubular barrel. The dispersion funnel assembly is configured to connect to the vial, and to be disposed at least partially within the tubular barrel. The dispersion funnel assembly has an open configuration to disperse the biological material from the vial into the tubular barrel between the dispersion funnel assembly and the filter assembly, and a closed configuration to force the dispersed biological material through the filter assembly when the dispersion funnel assembly is moved toward the dispensing end of the tubular barrel.