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 present invention generally relates to a system and process for producing a biosurfactant, and more particularly to a system and process for producing a biosurfactant from at least one strain of Bacillus subtilis, and formulations which comprise the biosurfactant.

A reactor system includes a support housing having an interior surface bounding a chamber, the chamber having a vertically extending central longitudinal axis. A flexible bag is disposed within the chamber of the support housing and has an interior surface bounding a compartment. A mixing element is disposed within the compartment of the flexible bag. A drive element, such as a drive shaft, is secured the mixing element, wherein the mixing element is laterally offset from and/or is angled relative to the vertically extending central longitudinal axis of the support housing.

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.

The purpose of the present invention is to efficiently dispense cells while reducing the risk of incorporating bacteria, etc. A cell dispensing device 1 includes: a first tube 23a which connects a container 21 and a dispensing container 22; a syringe pump 24 attached to a second tube 23b connected to a branching portion 31 formed on the first tube 23a; and a buffer tank 25 provided between the syringe pump 24 and the branching portion 31. In addition, a cell suspension contained in the container 21 is temporarily stored in the buffer tank 25 by means of the syringe pump 24, and the cell suspension stored in the buffer tank 25 is delivered to the dispensing container 22.

Bioreactor systems can include a first frame and a second frame, a well plate, a motor plate, a motor, and a controller. The first frame may define a well plate inset and standoff insets for a first set of metal standoffs. The second frame may define a plurality of mounts and a plurality of insets for a second set of metal standoffs. A gear may be positioned in each of the plurality of mounts. A paddle may be coupled to each of the gears. The well plate can be positioned within the well plate inset. The motor plate can be supported by and connected to the first set of metal standoffs and the second set of metal standoffs. The motor can be mounted on the motor plate and operatively connected to one of the plurality of gears.

Provided is a reaction apparatus for comprehensively measuring biodegradability of a material, comprising a device frame, an electrical control cabinet and a reaction chamber monomer. The upper side of the reaction chamber monomer is a reaction chamber body, and the lower part is a material receiving trolley. The top of the reaction chamber body is sealed by a chamber cover. A side wall is pasted with an electric heating plate and a thermal insulation cotton. A stirring paddle is arranged inside. An air inlet and an air outlet are respectively provided on a front and a rear wall. A discharging mechanism is located below. The electrical control cabinet separately controls the reaction conditions of each reaction chamber monomer. The present invention further relates to a use method thereof, which can realize the biodegradability evaluation in such three aspects as material degradation rate, disintegration rate and ecological non-toxicity test.

The present set of embodiments relate to a bioproduction system, method, and apparatus for creating a scalable bioreactor system. Specifically, the present set of embodiments enable the determination of bioreaction performance characteristics of a commercial scale by matching operational parameters between a small test scale bioreaction to that of a commercial scale bioreaction. The system and methods do not rely on simply making bioreactor apparatuses across scales the same dimensionally which would not account for differences in fluid dynamic properties between very small to very large volumes, but requires tuning of a variety of systems (mixing assembly, sparger system, and headspace airflow system) in conjunction with one another to achieve predictive outcomes.