A bioreactor has a container, an end plate, an agitator, a drive unit, and at least one field device arranged in the interior, field device electronics, a data transmission unit arranged on the end plate, and a motor head piece coupled in terms of energy to the drive unit. At least one communication unit is coupled in terms of signaling to the motor head piece and includes an adapter piece, having adapter electronics which are electrically connected to the field device electronics of the field device, and a communicator piece. The adapter piece and the communicator piece are separate components which can be coupled to one another, wherein the motor head piece is a separate component which can be coupled to the communication units.

An inverted conical bioreactor is provided for growing cells or microorganisms. The bioreactor has an internal space and a perforated barrier within the vessel, through which a liquid may flow, where cells or microorganisms cannot pass through the perforated barrier. The perforated barrier divides the internal space of the bioreactor into a first chamber and a second chamber. Cells are grown within the second chamber and can be perfused by re-circulating the liquid, for example a growth medium, through the bioreactor. Various inlet ports and outlet ports allow controlling the parameters of flow of the growth medium.

A method for optimizing a process (PROC) to produce a biochemical product (P) defined by a quality attribute, the process being controlled by an actuation parameter (C) and being monitored to get a measured value (T). The method includes training a predictive model (PRED) on a training database; and deploying the trained predictive model (PRED) to provide a correction actuation parameter (dC) when a predicted quality attribute (pQA) is out of a targeted quality attribute interval (QAmin, QAmax). The method also includes a step of designing a physical model of the process (PROC) able to provide a simulated quality attribute, the training database comprising simulated quality attributes computed from the physical model and experimental quality attributes computed from biochemical products (P) previously produced.

The present disclosure provides advantageous rotary interfaces for fluid assemblies (e.g., rotary interfaces for fluid flow in bioreactor applications), and related methods of fabrication and use. More particularly, the present disclosure provides improved rotary interfaces for fluid flow through porous impellers for filtration and/or sparging for fluid assemblies (e.g., bioreactor applications), and related methods of fabrication and use. Disclosed herein is a fluid assembly (e.g., bioreactor) that includes a porous impeller which is in fluid communication with a hollow shaft that can be used to transport a reaction fluid to an external storage tank or the like. The fluid assembly/bioreactor can include a coupling mechanism that transmits rotary motion from a motor to a primary shaft and then to a hollow secondary shaft, while at the same time permitting removal of a filtrate from the fluid assembly or bioreactor via the hollow secondary shaft and a porous impeller.

Disclosed herein are compositions, devices, methods, processes, and systems for culturing of large quantities of mammalian cells in suspension culture. Also disclosed are unique and surprising cell populations derived from the disclosed methods, processes, and systems. In many embodiments, the cells are cultured in suspension in liquid culture media that is agitated to maintain the cells in suspension, and agitation increases to maintain cells in suspension while growing and dividing to create cell spheres. The disclosed devices, methods, processes, and systems are useful in tailoring characteristics of the resulting cells based on characteristics of donor subject/initial cells. The disclosed cell populations are useful in treating subjects with cell based therapies in need thereof for various diseases and conditions.

The present set of embodiments relate to a system, method, and apparatus controlling a cell culture media mixing system. The control system includes an integrated control unit capable of controlling a broad ranges of peripheral devices commonly used in bioproduction through a graphical user interface displayed on a touch sensitive screen. The bioproduction system is designed to be highly customizable through process modification and recipe creation by user with little or no knowledge of programming and is capable of controlling a wide variety of devices using a single unit. The bioproduction system allows for auto-detection, auto-calibration, and automatic of device related processes into a bioproduction workflow.

The bioenvironmental simulation device according to an embodiment of the present invention includes at least one mounting unit on which cells to be measured are placed, a rotational force application unit configured to rotate the mounting unit so as to apply a rotational force to the cells to be measured placed on the mounting unit, and a culture liquid flow device through which a culture liquid flows across the mounting unit, wherein the culture liquid flows by the culture liquid flow device so as to apply a shear force to the cells to be measured.

The present invention relates to a bioreactor assembly comprising a plurality of trays (30) for holding a cell culture bag, a holder (2) on which the trays are mounted side by side to form a first series of trays rocking mechanism (4) for rocking the trays, the rocking mechanism (4) being operatively connected to each of the trays (30). The invention also relates to a bioreactor system (100) comprising at least one bioreactor assembly.

A cell cultivation apparatus for cultivating microorganisms and growing cells at high density is provided. The apparatus includes a membrane comprising multiple surface features on a first side of the membrane for cell placement. The surface features comprising one or more compartments within which a cell can be located. The membrane includes a material that is at least partially permeable to gas. A second side of the membrane defines a gas region. The second side of the membrane is separated from the first side of the membrane by the membrane. The apparatus further includes a media region for receiving media. The compartments are configured to at least partially reduce media flow shear forces on one or more cells in the compartments. The surface features may be ridges, protrusions, fins, wells, and/or posts.

A bioreactor for producing hydrogen gas and other metabolites. The bioreactor utilizes light, fermentation, and other metabolic processes for the production of metabolites, derived from various microorganisms contained within the bioreactor through respective metabolic pathways. The bioreactor comprises a main reactor chamber, a semipermeable membrane, a sleeve, a power supply, a substrate medium, a heating member, a plurality of tubing members, a collection reservoir, a pressure-sealed connecter member, and an agitator.