Algae harvesting and cultivating systems and methods for producing high concentrations of algae product with minimal energy. In an embodiment, a dead-end filtration system and method includes at least one tank and a plurality hollow fiber membranes positioned in the at least one tank. An algae medium is pulled through the hollow fiber membranes such that a retentate and a permeate are produced.

A product concentration device that utilizes a reservoir connected to a hollow-fiber filter element where the reservoir can serve as a container for filtrate emanating from another filtering device, such that product in the reservoir can be stored, concentrated and/or further processed as desired. Enclosed reactor systems, each of at least three chambers, fluid flow between the chambers controlled by selectively permeable barriers, flow controlled by an alternating flow diaphragm pump.

Disclosed herein are robust disposable alternating tangential flow (ATF) housing and diaphragm pump units and associated methods of manufacturing, testing, wetting, and using the same.

A liquid cell culture medium collecting filter unit includes a porous metal membrane that filters out cells in a liquid cell culture medium, a support that holds a peripheral portion of the porous metal membrane. and a tubular member that has a hollow part serving a flow path for a liquid cell culture medium. The tubular member is connected to the support such that the flow path faces at least part of a main surface of the porous metal membrane.

A multiport device for connecting a loop, preferably a tangential flow filtration loop or a sensor loop, to one port of a bioreactor, preferably a single-use bioreactor, is configured to be fixed to the port of the bioreactor. The multiport device includes a first flow path configured for withdrawing fluid from the bioreactor, and a second flow path configured for supplying fluid to the bioreactor. The first flow path has a first end adapted to be in fluid connection with the bioreactor, and a second end adapted to be connected to an inlet of the loop. The second flow path has an outer end adapted to be connected to an outlet of the loop, and a mouth adapted to be in fluid connection with the bioreactor. The mouth of the second flow path is distanced from the first end of the first flow path by at least 5 mm, preferably 10 mm.

Embodiments described herein generally provide for expanding cells in a cell expansion system. The cells may be grown in a bioreactor, and the cells may be activated by an activator (e.g., a soluble activator complex). Nutrient and gas exchange capabilities of a closed, automated cell expansion system may allow cells to be seeded at reduced cell seeding densities, for example. Parameters of the cell growth environment may be manipulated to load the cells into a particular position in the bioreactor for the efficient exchange of nutrients and gases. System parameters may be adjusted to shear any cell colonies that may form during the expansion phase. Metabolic concentrations may be controlled to improve cell growth and viability. Cell residence in the bioreactor may be controlled. In embodiments, the cells may include T cells. In further embodiments, the cells may include T cell subpopulations, including regulatory T cells (Tregs), for example.

Embodiments described herein generally relate to methods and systems for configuring settings of a cell expansion system including a bioreactor. Through a user interface, a user may configure display settings, system settings, and settings associated with protocols for loading, growing and/or harvesting cells. In configuring settings for protocols and associated processes, a diagram view or window of the cell expansion system is displayed in embodiments. The diagram view displays the process settings as graphical user interface elements. Settings available for configuration are enabled for selection in the diagram view. The diagram view allows the user to visualize the settings available for task configuration and to configure enabled settings. Configured settings are stored and capable of retrieval for subsequent execution or modification of the applicable protocol.

The present disclosure relates to cultured tissue, methods for production of the cultured tissue, and a bioreactor system for production of the cultured tissue. In some embodiments, the production of the cultured tissue may involve, at a first bioreactor, feeding a fiber scaffold into a chamber containing culture media, seeding the chamber with precursor cells, and allowing the precursor cells to proliferate and differentiate on a surface of the fiber scaffold. At downstream bioreactors, the production of the cultured tissue may further involve twisting a plurality of the cell-laden fibers to provide a cell-laden yarn, and weaving or knitting the cell-laden yarn into a three-dimensional (3D) structure. In some embodiments, the cultured tissue may be whole muscle cultured meat composed of muscle cell-laden fibers and fat cell-laden fibers. The whole muscle cultured meat may have a structural organization and hierarchy that mimics natural skeletal muscle tissue.

Embodiments described herein generally relate to methods and systems for customizing protocols for use with a cell expansion system. Through a user interface, a user may create a custom task for loading, growing and/or harvesting cells. A custom task may comprise one or more steps, in which a user may add or omit steps, as desired. Data may be entered for settings associated with a custom task, in which embodiments provide for such data to be entered each time the custom task is performed. In another embodiment, the settings for a custom task may be configured, in which such settings may be stored and retrieved upon selection of the custom task. Customization and configuration of a custom task may occur using a diagram view of the cell expansion system, in which process settings are associated with graphical user interface elements.

Proposed are a three-dimensional structuring method of cells and a three-dimensional structuring system of cells capable of efficiently bonding multiple cell clusters in a three-dimensional direction, pursuant to their growth, while ensuring safety. A plurality of fibers, in which one end of each of the fibers is held by a flat plate, are inserted together with the flat plate into a flow path through which a culture solution is supplied, a plurality of cell clusters are placed in the flow path upon causing the cell clusters to run with a liquid flow of the culture solution, and each of the cell clusters is cultured by being stacked on an outer surface of each of the fibers with the flat plate as a growth origin.