A continuous automated perfusion culture analysis system (CAPCAS) comprises one or more fluidic systems configured to operate large numbers of biodevices in parallel. Each fluidic system comprises an input reservoir plate for receiving media; a biodevice plate comprising an array of biodevices fluidically coupled to the input reservoir plate, configured such that each biodevice has independent media delivery, fluid removal, stirring, and gas control, and each biodevice is capable of continuously receiving the media from the input reservoir plate; and an output plate fluidically coupled to the biodevice plate for real-time analysis and sampling. The operations of the CAPCAS are automated and computer-controlled wirelessly. The CAPCAS can also be used for abiotic and biotic chemical synthesis processes.

A continuous automated perfusion culture analysis system (CAPCAS) comprises one or more fluidic systems configured to operate large numbers of biodevices in parallel. Each fluidic system comprises an input reservoir plate for receiving media; a biodevice plate comprising an array of biodevices fluidically coupled to the input reservoir plate, configured such that each biodevice has independent media delivery, fluid removal, stirring, and gas control, and each biodevice is capable of continuously receiving the media from the input reservoir plate; and an output plate fluidically coupled to the biodevice plate for real-time analysis and sampling. The operations of the CAPCAS are automated and computer-controlled wirelessly. The CAPCAS can also be used for abiotic and biotic chemical synthesis processes.

A polymeric substrate has a plasma treated contact surface which is roughened, hydrophilic and has a higher oxygen atomic content than the interior portion. The treated contact surface has an enhanced cell adhesion, cell growth and cell recovery rate. During the treatment, the contact surface is contacted with a process gas introduced through a gas inlet near the treated surface and radio frequency electrical power is introduced in the process gas, forming a treated contact surface that has improved cell recovery compared to an untreated contact surface. The process gas optionally can be nitrogen gas, oxygen gas, or a gas that contains nitrogen atoms, oxygen atoms, or a combination of nitrogen and oxygen atoms. The process optionally improves cell recovery of a chicken embryo cell culture from the treated contact surface.

The present invention relates to methods for production of undifferentiated or differentiated embryonic stem cell aggregate suspension cultures from undifferentiated or differentiated embryonic stem cell single cell suspensions and methods of differentiation thereof.

Embodiments relate to systems and methods for increasing the cell growth surface within the roller tubes used as reaction vessels in a cell culture system by using a rotating platform or cage-like structure with a center of rotation of each of roller tubes being held therein being coaxial with the circumferential distribution of the plurality of roller tubes held in the platform. Each of the roller tubes has a superellipse or squircle cross-sectional shape to further increase the cell growth surface within the roller tubes. Additional improvements include use of a removable cell adherence liner, a cell perfusion system, a cell culture monitoring system, and a gas circulation system.

The present invention relates to methods for production of undifferentiated or differentiated embryonic stem cell aggregate suspension cultures from undifferentiated or differentiated embryonic stem cell single cell suspensions and methods of differentiation thereof.

An apparatus for processing cells is disclosed. In one embodiment, a fixed bed reactor is provided for the cells, the fixed bed reactor including a portion movable from a first position corresponding to a packed condition of the fixed bed to a second position corresponding to a depacked condition of the fixed bed. Movement of the partition facilitates harvesting of the cells there from. Related apparatus, kits, methods, and systems are also disclosed.

A polymeric substrate is contacted with a process gas and radio frequency electrical power is introduced in the process gas, forming a treated contact surface that has improved cell recovery compared to an untreated contact surface. The process gas optionally can be nitrogen gas, oxygen gas, or a gas that contains nitrogen atoms, oxygen atoms, or a combination of nitrogen and oxygen atoms. The process optionally improves cell recovery of a chicken embryo cell culture from the treated contact surface.

Disclosed is a rotating culture vessel based on a rotating culture technology using an RWV, by which cell seeding, liquid medium exchange, quality control and so on can be automated and degassing can be conducted simultaneously with liquid medium exchange without disturbing the cells under culture. Also disclosed is an automatic cell culture apparatus using the same. A rotating culture vessel, which contains cells and a liquid culture medium, to be attached to a horizontal rotating shaft of a rotating culture device to three-dimensionally culture the cells, wherein one or more inlets/outlets for supplying cells and a liquid culture medium at the early stage and then taking out the cultured cells, are formed at appropriate position of a flat cylindrical culture container; at least one pair of a supply port and a discharge port for liquid medium exchange is provided on the outer circumferential cylindrical face of the culture container.

A continuous automated perfusion culture analysis system (CAPCAS) comprises one or more fluidic systems configured to operate large numbers of biodevices in parallel. Each fluidic system comprises an input reservoir plate for receiving media; a biodevice plate comprising an array of biodevices fluidically coupled to the input reservoir plate, configured such that each biodevice has independent media delivery, fluid removal, stirring, and gas control, and each biodevice is capable of continuously receiving the media from the input reservoir plate; and an output plate fluidically coupled to the biodevice plate for real-time analysis and sampling. The operations of the CAPCAS are automated and computer-controlled wirelessly. The CAPCAS can also be used for abiotic and biotic chemical synthesis processes.