A disposable, fabrication-free, high-volume electroporation device may process cell samples of large volume without compromising transformation efficiency and cell viability, while precipitously reducing the entire processing time and effort. An embodiment includes at least two hollow, tubular conductive elements and an insulating structure, defining a channel, that fluidically couples the at least two conductive elements to define an electroporation flow path in the channel for flow-through electroporation. The high-volume electroporation device can be an alternative to cuvettes for typical volume electroporation, but can also be an indispensable tool to process large volume samples for applications, such as creation of modified sample libraries.

Provided is a culture vessel for adherent cells that has a large culture portion surface area and ensures easily dissociating and recovering cells without consuming a medium or a dissociation solution more than necessary. The bag-shaped adherent cell culture vessel made of flexible packaging material includes a vessel body portion having a first vessel wall and a second vessel wall and one or more injecting/ejecting ports. The vessel body portion has an intermediate culture wall between the first vessel wall and the second vessel wall. A culture chamber is disposed in each of between the first vessel wall and the intermediate culture wall and between the second vessel wall and the intermediate culture wall, and a flow passage communicating between the respective culture chambers is disposed.

The present invention provides fluidic (both air and liquid) exchange systems configured to retrofit standard cell/tissue culture well plates (6, 12, 24, 48, 96, 384, 1536 wells, and the like) and petri dishes by plugging into the openings of each well or dish.

The present invention provides a buffer preparation and transfer system for a process of manufacturing an antibody pharmaceutical which can reduce the input of a lot of labor due to the preparation of each buffer, including the weighing of a buffer chemical, the input of a powder, stirring and transfer, and significantly shorten process time by positioning and designing components in a manner that automates the preparation and transfer of various buffer solutions using a control unit and controls the concentration and composition of a buffer by transferring a concentrated component solution into the buffer storage tank using an opening/closing valve and a flow rate-adjusting valve, and unlike the related art, reduces the number of buffer preparation tanks corresponding to individual buffer storage tanks, which is advantageous for securing a safe distance between processes and securing a facility area.

The present invention relates to a Disposable Bioprocess System consisting of a Single-Use-Bioreactor, a Single-Use-Pump and a single-use micro-organism retention filter. Combined most suitable for cultivation of suspended micro-organisms in a liquid media at high micro-organism concentration in a perfusion mode continuous process for expression of biological material. The inlet port of the liquid Single-Use-Pump connects via a valve to the broth reservoir of the Single-Use-Bioreactor through a liquid conveying port. The outlet port of the liquid pumping Single-Use-Pump connects via a valve to a micro-organism retention filter. And a method for operating said sterile Disposable Bioprocess System in perfusion mode for continuously processing.

A cell culture method is a cell culture method for arranging cultured cells in a culture dish and continuously culturing the cultured cells by supplying a liquid required to grow or maintain the cultured cells to the culture dish and discharging the liquid from the culture dish. The cell culture method includes: providing a supply port of the liquid at one end of the culture dish and providing a discharge port of the liquid at other end of the culture dish so as to sandwich the cultured cells between the supply port and the discharge port, and discharging the liquid while supplying the liquid to the culture dish so that a moving linear velocity of the liquid from the supply port toward the discharge port is less than a maximum velocity at which shear stress is not applied to the cultured cells.

The invention relates to a long term cell culturing method and a cell culturing apparatus and kit that employ a porous polyimide film. The invention further relates to a cell cryopreservation method and kit employing the porous polyimide film.

A bioprocessing system comprising a series of processing stations for performing operations for bioprocessing is disclosed. The bioprocessing system includes an automated system comprising means for manipulating a fluid connection between a first container and a separable second container whereby to create an aseptic connection that enables a controlled transfer of fluid or cell material between the first container and the second container, wherein the means for manipulating a fluid connection is configured to create an aseptic connection that can be disconnected after the transfer of fluid or cell material is complete to enable a further such fluid connection to be manipulated between the first container and a separable third container, and means for controlling an automated sequence of operation of the processing stations.

An apparatus is described which includes at least one reactor, at least one linear piston pump, the or each piston pump including a tube, a piston and an arm coupled to the piston, the or each piston pump arranged to inject feedstock to a respective reactor, a beam or plate coupled to the arm(s) of the piston pump(s) configured to linearly drive the piston(s) and a linear actuator for driving the beam or plate. The piston pump has a volume of at least 50 milliliters and an output port having a diameter of at least 5 mm.

A separation system, a method in a separation system and an elution arrangement to be provided in a separation system for separating a biomolecule from a cell culture are provided. The method comprises the steps of: —providing a feed from a cell culture (3; 103; 203) comprising said biomolecule to a magnetic separator (5; 105; 205) and providing to the magnetic separator magnetic beads comprising ligands capable of binding this biomolecule; —separating by the magnetic separator said magnetic beads with bound biomolecules from the rest of the feed; —forwarding said magnetic beads as a slurry with an added buffer to an elution cell (7; 107; 207); —eluting the bound biomolecules in the elution cell.