The present invention relates to a novel bioreactor system for preparing an engineered three- dimensional biological tissue construct. The bioreactor system comprises a cultivation chamber that is designed to allow the formation, cultivation and the subsequent testing and/or stimulation of tissue constructs on one or more support elements with a minimum risk of microbial contamination or mechanical damage The invention furthermore relates to a method for preparing an engineered tissue construct using the novel bioreactor system. The invention also relates to the use of the bioreactor system for preparing engineered biological tissue constructs, preferably tissue constructs which are suitable for being used in clinical tissue replacement and reconstructive therapy, drug development, drug screening, toxicity testing, cosmetic studies, safety testing, developmental studies, disease modeling, or food purposes.

The invention relates to an installation (1) for the three-dimensional printing of a medical device directly at a location where the medical device is to be used.

According to the invention, the installation comprises a container (2) comprising inside it: a production module (3) comprising a 3D printer (6); a clean room (4) comprising means (12) for washing and disinfection of the printed medical device, and a machine (13) for packaging the washed and disinfected medical device.

A method is provided for vaporized hydrogen peroxide cleaning of a chamber. The method includes altering a temperature of air in the chamber from an initial temperature to a sterilization temperature over a first time period. The method also includes injecting vaporized hydrogen peroxide into air in the chamber to alter a relative humidity of hydrogen peroxide vapor in the chamber to a sterilization level over the first time period. The method also includes maintaining the temperature at the sterilization temperature and the relative humidity at the sterilization level over a second time period. The method also includes reducing the relative humidity from the sterilization level to a safe level over a third time period. In one embodiment, the method is provided for vaporized hydrogen peroxide cleaning of an interior chamber of an incubation container. In other embodiments, the incubation chamber featured in the method is provided.

A movable cell incubator contains: a body, a first lid, a second lid and an electric control unit. The body includes a first internal space, a refrigeration room, and an airtight culture room. The first lid airtightly covers the culture room, the second lid airtightly covers the refrigeration room, and the control unit includes a microprocessor, a power module, a digital/analog conversion module defined between a microprocessor and the power module, a heating module controlling temperature of the culture room, a cooling module supplying cold source to the refrigeration room, a peristaltic pump module, a flow sensing module, a CO2 detective supply module supplying CO2 to the culture room, and a setting display module exposing and fixed on the first lid, with the peristaltic pump module aseptically connected between cell culture media and cell culture bag by multiple conveying tubes.

The present invention relates to a biological (eg cell) processing assembly comprising an aseptic chamber with apertures adapted for gloves to fit and an incubation chamber connectable to aseptic chamber with transfer hatches, doors secured by multi-walls and inflatable seals, stepped collars for tight closure of doors and closed interaction between the chambers. From the aseptic chamber it can be reached through into incubation chamber. There is a docking spigot on outlet wall to interact with stepped collar to define transfer port between the chambers and a disinfectant delivery device to disinfect transfer port.

A sample storage apparatus includes: a lid member; a sample storage container; first and second fluid sucking sections; first and second fluid discharging sections; first to fourth flow paths; and a first fluid identification sensor. The first flow path is connected to the first fluid sucking section, the second flow path is connected to the second fluid sucking section, the third flow path is connected to the first fluid discharging section, and the fourth flow path is connected to the second fluid discharging section. The first fluid identification sensor for identifying a fluid is disposed in the first flow path.

A device for the decentralized and continuous production of biomass at home, which comprises: a culture container for continuous processes, in batch and in a fed batch connected to a system that provides gaseous components; and all the supplied components are sterilized by a filter; a solids dispenser that is connected to a solids reservoir, and which can quantify the dispensed solids; a dissolving-unit that is connected to the solids dispenser, to a liquids metering pump, and to a purified water generation system, and where the dissolving-unit exit is connected to the culture tank by the culture medium filters; and the latter communicate the fluids with the dissolving-unit and the culture tank; a device that contains and dispenses the inoculum that initiates the culture, and which is connected to the culture tank; a temperature-controlled rotary drum system is connected to the culture tank to separate the biomass, with a drain of liquids; a sterilizer is connected to the culture tank and the associated filters; a microprocessor with instructions to control the variables of the process, which is connected to a user interface; and connections to a water source, electric power source, drain of liquids, and to Internet and servers with AI. Procedure for the continuous production at home of biomass using said device.

The present invention provides a system for the insertion of a pre-sterilized sensor probe into a sterile vessel. The system of the invention provides a reliable and straightforward way to insert one or more sterile probes into a sterile vessel. The present invention also provides a sterile vessel that includes one or more of the systems of the invention. The sterile vessel can be a flexible or semi-rigid bag or tubing of the type typically used for carrying out biochemical and/or biological processes and/or manipulating liquids and other products of such processes. Furthermore, the present invention provides a method for aseptically inserting a probe into a sterile vessel where the method makes use of the system of the invention.

A cell culture device for culturing cells in a closed container kept in an aseptic state includes: a chamber including an opening/closing part capable of being opened and closed; a connection path configured to connect closed containers accommodated in the chamber to each other and each having an inside kept in an aseptic state; a driving part configured to move cells from one closed container to the other closed container via the connection path; and a container attachment/detachment device. After the cells are moved from one closed container to the other closed container, the container attachment/detachment device is configured to remove one closed container from the connection path while maintaining an aseptic state inside the other closed container and the connection path, and connect a new closed container loaded into the chamber to the connection path while maintaining an aseptic state inside the new closed container.

A bag assembly for use with a heat exchanger includes a flexible bag having of one or more sheets of polymeric material, the bag having a first end that bounds a first compartment and an opposing second end that bounds a second compartment, a support structure being disposed between the first compartment and the second compartment so that the first compartment is separated and isolated from the second compartment. A first inlet port, a first outlet port, and a first drain port are coupled with the flexible bag so as to communicate with the first compartment. A second inlet port, a second outlet port, and a second drain port are coupled with the flexible bag so as to communicate with the second compartment.