A cell cryopreservation pretreatment operation plate includes a planar operation portion, a first recess for storing a treatment solution, a second recess for storing a treatment solution, a third recess for storing a treatment solution, and a fourth recess for storing discarded solutions. The planar operation portion includes, on a surface thereof, a first circular segment, second circular segment, and third circular segment for placing treatment solutions, an enlarged first circular segment enclosing the first circular segment, an enlarged second circular segment enclosing the second circular segment, and an enlarged third circular segment enclosing the third circular segment.

A cell cryopreservation pretreatment operation plate includes a planar operation portion, a first recess for storing a treatment solution, a second recess for storing a treatment solution, a third recess for storing a treatment solution, and a fourth recess for storing discarded solutions. The planar operation portion includes, on a surface thereof, a first circular segment, second circular segment, and third circular segment for placing treatment solutions, an enlarged first circular segment enclosing the first circular segment, an enlarged second circular segment enclosing the second circular segment, and an enlarged third circular segment enclosing the third circular segment.

The present invention refers to a temperature resistant dental implant container with dental implant comprising a polygonal or cylindrical, optically transparent container with a conically tapered interior for receiving a dental implant, a needle-pierceable, flexible, and liquid-tight septum, a lid which is separably connected to the container, wherein the interior of the container is configured to fix the position of the dental implant between the bottom of the septum and the bottom of the interior, and a dental implant comprising a conditioned surface. Further its use for transport and storage, and a method for in vitro cellular coating a dental implant are described.

The present invention refers to a temperature resistant dental implant container with dental implant comprising a polygonal or cylindrical, optically transparent container with a conically tapered interior for receiving a dental implant, a needle-pierceable, flexible, and liquid-tight septum, a lid which is separably connected to the container, wherein the interior of the container is configured to fix the position of the dental implant between the bottom of the septum and the bottom of the interior, and a dental implant comprising a conditioned surface. Further its use for transport and storage, and a method for in vitro cellular coating a dental implant are described.

Systems and methods of the invention generally relate to prolonging viability of bodily tissue, especially lung tissue, through the use of an expandable accumulator to maintain a constant pressure within the lumen of the organ even during external pressure fluctuations due to, for example, flight. Systems and methods may include prolonging donor organ viability in storage through the use of an organ container that mimics the geometry and orientation of the organ in vivo.

Systems and methods of the invention generally relate to prolonging viability of bodily tissue, especially lung tissue, through the use of an expandable accumulator to maintain a constant pressure within the lumen of the organ even during external pressure fluctuations due to, for example, flight. Systems and methods may include prolonging donor organ viability in storage through the use of an organ container that mimics the geometry and orientation of the organ in vivo.

Systems and methods herein generally relate to prolonging viability of bodily tissue, especially an organ, 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. The systems and methods herein can include an electronic pump that pumps gas into an organ and a mechanical pressure regulator to release gas based on organ pressure.

Systems and methods herein generally relate to prolonging viability of bodily tissue, especially an organ, 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. The systems and methods herein can include an electronic pump that pumps gas into an organ and a mechanical pressure regulator to release gas based on organ pressure.

Systems and methods are provided for identifying a cryogenic sample. An identification tag for cryogenic storage includes an identification portion, a retention portion, and the tether portion. The identification portion defines a retention opening a label opening that is sized to receive a label. The retention portion is sized to be received by the retention opening and at least partially occlude the label opening. The tether portion extends between the identification portion and the retention portion. The tether portion is threaded through a portion of a cryogenic storage container and the retention portion is received by the retention opening to couple the identification tag to the cryogenic storage container.

Systems and methods are provided for identifying a cryogenic sample. An identification tag for cryogenic storage includes an identification portion, a retention portion, and the tether portion. The identification portion defines a retention opening a label opening that is sized to receive a label. The retention portion is sized to be received by the retention opening and at least partially occlude the label opening. The tether portion extends between the identification portion and the retention portion. The tether portion is threaded through a portion of a cryogenic storage container and the retention portion is received by the retention opening to couple the identification tag to the cryogenic storage container.