A holding tool is configured to be used together with a container and a lid for the container to sandwich the container and the lid. The holding tool includes a base on which the container is placed, and a cover configured to cover the lid. The base and the cover each have an opening at a central portion and are configured to engage with each other to press and sandwich the container and the lid upward and downward.

The present invention efficiently and cost-effectively extracts and collects cells from a tissue. The inventors have discovered that the tissue can be effectively fragmented and the resulting cells can be purified using a system or kit with multiple components. An advantage of the present invention is that tissue processing takes place in a closed system such that sterility can be maintained throughout the process, even if certain components are removed during processing, for example through the use of valves, clamps, and heat seals. Furthermore, any or all of the steps can be automated or manually accomplished, according to the specific needs of the application or the user.

The present invention relates to a shielding device to reduce the impact of radiation, that contains a container (10) with a receptacle (14) and a functional filling (20) placed into the receptacle (14) of the container (10), where the functional filling (20) is composed of a collecting component (21) that contains a mixture of inorganic substances and a utilizing component (22) that contains a mixture of organic components.

An article including, either: a frame having an interior cavity, and a flexible liner situated within the interior cavity; or a deformable frame having an interior cavity, as defined herein.
Either frame can receive a sample, such as liquid having suspended live cells, and cooling freezes the sample to a solid sample. The solid sample can be readily ejected from the article having either a frame with the flexible liner, or the deformable frame, without extensive thawing. The solid sample can be rapidly displaced from the article by the methods and apparatus disclosed herein.

The carriers that are available in the market don't maintain all the necessary parameters that I am mentioning in my invention. Many of them are: 1) Costly 2) Allow the transport of cells for short period of time 3) Are suitable for transporting certain type of cells 4) Don't include control for all the parameters that are required for the experiments 4) Need extra steps which can affect the experiment/organs and waste the time, efforts and money of the researchers. 5) Limit the researchers for using containers with certain sizes and materials.

Alternatively, the Mini-incubator carrier box in my invention is an economic transport system. It enables the researchers to fix different containers using clamps and screws and to transport the organs/samples/cells in any container for long period of time and long distance under optimized conditions without the need of extra steps/costs.

The present invention is a method of freezing cells comprising the steps of incubating said cells in a solution comprising a cryoprotective agent, concentrating the cells resulting from the previous step withdrawing the eluent essentially free of cells, and freezing the resulting concentrated cells. The cells frozen by the invention's method render a high post-thawing viability, reduce cryoprotectant related toxic events and promote cells life in a suspension state after thawing. The invention also comprises the container comprising the frozen cells.

A packaging bag for a cell culture vessel used for sealing a cell culture vessel, wherein when the packaging bag for a cell culture vessel sealing the cell culture vessel is accommodated in a closed space in which ordinary pressure is maintained, a temperature of 45 C. is maintained and the volume is 170 L, and the total amount of 70 mL of 6-mass % hydrogen peroxide aqueous solution is vaporized by applying ultrasonic vibration for 7 minutes in the closed space, and the hydrogen peroxide is decomposed by ultraviolet irradiation at a wavelength of 254 nm so that hydrogen peroxide concentration in the closed space becomes equal to or smaller than 1 mg/L within 90 minutes from the stop of the ultrasonic vibration, the amount of hydrogen peroxide adsorbed to the cell culture vessel is less than 3 ng/cm.sup.2.

A biological sample collection, storage, and transport device includes a collection assembly and a sheath, wherein the collection assembly includes a support shaft, a swab head, and a handle, the swab head mechanically couples to a distal support shaft end, the handle couples to a proximal support shaft end, and the collection assembly slideably couples to the sheath and is configurable in a retracted position with the swab head entirely disposed within the sheath or an extended position with the swab head extending outside of the sheath. A distal sheath end includes an aperture, the aperture having a circumference large enough to allow the swab head to pass through said aperture when the collection assembly is configured in the extended position, and a seal is applied to the distal sheath end after the swab head has collected a biological sample and the collection assembly has been reconfigured into the retracted position.

A coupling device configured to form a sample access assembly is provided. The sample access assembly is configured to house a sample. The coupling device includes a heating component and a separating component. Further, the separating component is configured to separate portions of first and second containers that form first and second compartments of the sample access assembly. Moreover, the heating component is configured to heat at least a portion of the sample.

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.