The invention relates to systems and methods for effective production and use of microorganisms and/or the fermentation broth in which they are produced. Advantageously, the system is cost-effective, scalable, quick, versatile, efficacious, and helpful in reducing resistance to chemical compounds and residue that concerns consumers.

A robot for transporting a biodevice from one place to another place, comprising a body for carrying the biodevice; a driving assembly for driving the body in omnidirectional motion; a sensing unit for sensing at least a position and orientation of the body; and a control unit coupled to the driving assembly and the sensing unit for generating one or more control signals based on at least the sensed position and orientation of the body to drive the driving assembly so as to move the body to a desired place and to arrive with the correct orientation.

A tube management system includes an elongated rack extending between a first end and an opposing second end; an elongated first shaft having a first end and an opposing second end, the first shaft being secured to the rack; a securing structure secured to the first shaft; a collapsible bag bounding a chamber; and a tubular member projecting from the collapsible bag, wherein the securing structure at least partially encircles the tubular member.

The present set of embodiments relate to a system, method, and apparatus for hydrating and mixing a liquid medium from a dry medium. Such systems, methods, and apparatuses can be used in the biotech industry because they can be used to provide prepackaged dry media in a format that can be quickly rehydrated free of issues with operator error found in more conventional media rehydration systems using mixing tanks and reactors.

An anaerobic digester is provided. The anaerobic digester includes a biogas storage container comprising a semi-permeable membrane separating the biogas storage container into a first space and a second space, such that the first space is configured to be methane enriched and the second space is configured to be CO.sub.2 enriched. The anaerobic digester further includes a cover positioned over the biogas storage container for protecting the biogas storage container against the elements.

A portable bioreactor is provided for driving displacement of at least one stirring sleeve relative to at least one tube cassette in a first direction and includes a machine frame unit and a first elevator. The first elevator includes a first linear movement module, a first transmission module, and a first turning module. The first linear movement module includes a first slider which is slidable on the first guide rail in the first direction between a first top position and a first bottom position. The first turning module is coupled to the first slider through the first transmission module so as to permit turning of the first turning module to be translated by the first transmission module into linear sliding movement of the first slider at a varying speed.

A mobile processing laboratory (MPL) is provided, configured for facilitating performing therewithin a cell therapy process. The MPL comprises a portable enclosure; one or more pieces of laboratory equipment for carrying out the cell therapy process and being housed within the enclosure; a plurality of sensors, each configured to measure information regarding the environment, cellular material of the process, and/or one of the pieces of laboratory equipment; and a computer system configured for management of the cell therapy process. The computer system is configured to facilitate collecting data from the sensors, and to optimize one or more activities associated with performance of the cell therapy process based on data collected from one or more other MPLs configured for performing therewithin substantially the same cell therapy process.

A biocontainment vessel includes a vessel structure including a structural composition and an enhancement composition associated with the structural composition. The enhancement composition includes a co-polymer. The co-polymer is a poly(glycerol sebacate) or a poly(glycerol sebacate urethane). The enhancement composition may also include an augmentation agent associated with the co-polymer. The enhancement composition is located with respect to the structural composition such that the enhancement composition benefits biological cells contained in the biocontainment vessel. A composition includes a co-polymer and an augmentation agent contained by the co-polymer. A method of containing biological cells includes placing the biological cells in an augmented biocontainment vessel and storing them in the augmented biocontainment vessel under predetermined conditions. An augmented substrate includes a substrate and an enhancement composition coating a surface of the substrate.

This method for producing a cell cluster group comprises: a step for putting, into a well, a cell suspension obtained by suspending dispersed cells in a medium, using a cell incubator which includes the well and two or more recesses formed in the bottom of the well and in which the area of an opening of each recess in plan view is at most 1 mm.sup.2; a step for centrifuging the cell incubator; and a step for culturing the dispersed cells in the recesses.

The invention relates to a cell culture carrier comprising a first channel and a reservoir, where the first channel and the reservoir are formed in the interior of the cell culture carrier, where the first channel has an inlet opening in an outer side of the cell culture carrier and an outlet opening in the outer side of the cell culture carrier, where the reservoir has at least two openings arranged next to one another, where the first channel is connected to the reservoir by the at least two openings, and where the reservoir is connected to the outer side of the cell culture carrier by no other channel.