A method and apparatus for separation of cells from suspension using single use components that include a flexible membrane mounted on a rigid frame that is supported within a multiple use rigid centrifuge bowl. Such single use components include a rotatable core which is rotated at a sufficiently high angular velocity to separate cell concentrate and centrate. Cell centrate and/or cell concentrate is removed from the interior of the core by a centripetal pump having a pair of curved volute passages. The volute passages are curved toward the direction of rotation of the core.

A method and apparatus for separating cell suspension into centrate and concentrate includes a solid wall rotatable centrifuge bowl (82). A single use rotatable core (88) is positioned in the bowl and bounds a cavity (90) which serves as a separation chamber. The bowl rotates about an axis (84). An inlet tube (92) and an outlet tube (102) extend along the axis in the bowl cavity. The centripetal pump (98) in the cavity is in connection with the outlet tube. The centrate discharge pump (120) is in connection with the outlet tube. A pressure damping reservoir (122) is fluidly connected between the outlet tube and the discharge pump. At least one control circuit (142) is operative to control the apparatus to maintain a positive pressure above atmospheric pressure within the cavity, so as to maintain the cell suspension away from at least one seal (106) that bounds the interior of the cavity.

The present disclosure relates to hollow fiber tangential flow filters, including hollow fiber tangential flow depth filters, for various applications, including bioprocessing and pharmaceutical applications, systems employing such filters, and methods of filtration using the same.

A method for separating a biological suspension includes dispensing a liquid suspension comprised of cells or microorganisms from a bioreactor or fermenter into a sterile compartment of a first bag assembly, the first bag assembly including a collapsible bag having of one or more sheets of flexible film. The compartment of the first bag assembly is sealed closed. The first bag assembly, either with or without a manifold fluid coupled therewith, is then rotated, such as by using a centrifuge, so that the liquid suspension separates within the compartment into a pellet comprised of the cells or microorganisms and a liquid supernatant.

A method and apparatus for separating cell suspension into centrate and concentrate includes a solid wall rotatable centrifuge bowl (82). A single use rotatable core (88) is positioned in the bowl and bounds a cavity (90) which serves as a separation chamber. The bowl rotates about an axis (84). An inlet tube (92) and an outlet tube (102) extend along the axis in the bowl cavity. The centripetal pump (98) in the cavity is in connection with the outlet tube. The centrate discharge pump (120) is in connection with the outlet tube. A pressure damping reservoir (122) is fluidly connected between the outlet tube and the discharge pump. At least one control circuit (142) is operative to control the apparatus to maintain a positive pressure above atmospheric pressure within the cavity, so as to maintain the cell suspension away from at least one seal (106) that bounds the interior of the cavity.

Disclosed herein are cell processing systems, devices, and methods thereof. A system for cell processing may comprise a plurality of instruments each independently configured to perform one or more cell processing operations upon a cartridge, and a robot capable of moving the cartridge between each of the plurality of instruments.

An apparatus for separating cell suspension material into centrate and concentrate, includes a single use structure (178, 240, 250) releasably positioned in a cavity in a solid wall rotatable centrifuge bowl (172). The bowl and portions of single use structure rotate about an axis (174). A stationary inlet feed tube (184), a centrate discharge tube (212) and a concentrate discharge tube (230) extend along the axis of the rotating single use structure. A centrate centripetal pump (208) is in fluid connection with the centrate discharge tube. A concentrate centripetal pump (216) is in fluid connection with the concentrate discharge tube. A controller (274) operates responsive to sensors (264, 270) in respective centrate and concentrate discharge lines (262, 268), to control flow rates of a concentrate pump (272) and a centrate pump (266) to produce output flows of cell concentrate and generally cell free centrate.

A method for incubating reagents, suspensions and/or biological products to a predetermined temperature for biological testing; the method comprising the steps of: a) providing a selected biological product in a receptacle and which is required to be incubated to a temperature which simulates a natural thermal environment of the biological product; b) applying controlled heating to or near the biological product using at least one laser emitting from a laser source for a time sufficient to reach a target temperature or which simulates a target temperature of the natural thermal environment in which the biological product exists.

A method for operating a bioprocess installation with an electronic process control and at least one bioprocess unit, wherein the bioprocess unit comprises a cell broth source with a first receptacle for cell broth including cultivation media and cells, establishing a culture environment for cell cultivation and/or bio production, wherein the bioprocess unit comprises a clarification setup with a centrifuge for the clarification of the cell broth by centrifugation, with a liquid pumping arrangement assigned to the centrifuge and with a liquid network with a number of liquid lines communicating with the liquid pumping arrangement, wherein out of a first culture environment established by the first receptacle, the cell broth is transfered to the centrifuge via the liquid network, which centrifuge is operated in a forward operation for cell separation and/or cell washing and in a backward operation for cell discharging.

An assembly includes an adjustable dip tube that can selectively withdraw an isolated component at various heights within a vessel. The adjustable nature of the dip tube can improve the cell recovery rate as compared to conventional cell recovery assemblies. Additionally, the assembly can take advantage of the adjustable nature of the dip tube while maintaining an aseptic interior cavity of the assembly.