An incubator (1) and its use for cultivating microorganisms and/or for carrying out a chemical reaction are provided. The incubator (1) has a sample vessel holder (3) for insertion of a sample vessel (4), a heating device (5) for changing a temperature in the sample vessel holder (3) and/or in a sample vessel (4) inserted into the sample vessel holder (3), and a sample-inactivating device (6) for inactivation of a sample (7) in a sample vessel (4) that is inserted into the sample vessel holder (3).

A connection clamping device (21; 61; 81; 131; 151) arranged for securing a flexible tube (1) to a barbed end (5b) of a tube connector (5), whereby the barbed end (5b) comprises a barb (9) and the tube connector during connection is arranged to protrude into an end of the flexible tube (1), characterized in that said connection clamping device comprises two sections (23 a, 23b) which, during connection when the tube connector protrudes into an end of the flexible tube, are arranged to be connected and locked to each other by a locking mechanism (33a,33b,34a,34b; 63a, 63b, 64a, 64b) around the tube connector (5) and the flexible tube (1), such that the flexible tube (1) is compressed against the tube connector (5) by a rib (41a, 41b) provided on the inner circumference of the connection clamping device.

A flow distribution device for bioprocess systems, comprising: ⋅—a flow distribution manifold (12; 112; 212; 312) comprising: ⋅o at least four fluid connection tubes (14), wherein each fluid connection tube (14) comprises a first end (18) for fluid connection and an opposite second end (20) ⋅o a central common compartment (30; 130; 230; 330) to which the second ends (20) of each of the fluid connection tubes (14) are connected, whereby the first ends (18) of each of the fluid connection tubes (14) can be in fluid communication with the central common compartment (30; 130; 230; 330) ⋅—at least three pinching members (41) which are provided in connection with one fluid connection tube (14) of the flow distribution manifold (12; 112; 212; 312) each, wherein each of said pinching members (41) can be controlled into at least a first and a second position, wherein in the first position for each of the pinching members (41) the pinching member pinches one of the fluid connection tubes (14) such that fluid flow is prevented between the first end (18) and the second end (20) of this fluid connection tube (14)

Disclosed are a process and an automated facility for manufacturing a purified protein of interest. The protein of interest can be a recombinant or naturally occurring protein and/or a therapeutic or other medically useful protein. For example, the disclosed process and automated facility are useful for manufacturing a purified protein drug substance.

The invention is comprised among apparatus and/or devices for manipulating and handling fluids. The invention relates to the integration of these apparatus and/or devices in a system for manipulating and/or handling any type of fluids. Specifically, the invention relates to a disposable cartridge and a platform cooperating with one another in a flexible system for manipulating fluids, as well as a flexible system for manipulating fluids. More particularly, the present invention is intended for culture cells.

A method for producing a single-use container, particularly a single-use bioreactor, an assembly system, and a single-use container particularly a single-use bag such as a single-use bioreactor comprising: a base material; and at least one functional element being at least partially connected with the base material, wherein the functional element is obtained by a three dimensional printing technique from at least one printable material, wherein the printable material is heated during the three dimensional printing thereby at least partly connecting the printed functional element to the base material.

Provided is a biological fluidic system that provides a high degree of sterilization by performing the biological processing in a closed system in which the fluid is contained in chambers that are isolated from the environment in a manner that does not permit ingress of contaminants.

The present invention provides a parallel bioreactor system, comprising: an oscillator for generating oscillating motion; a plurality of culture vessels mounted on the oscillator, wherein each culture vessel is provided with an inner cavity, the inner cavity comprises a cylindrical portion at the upper part and an inverted truncated conical bottom at the lower part, a cross section of the cylindrical portion is consistent with the cross section of the top of the inverted truncated conical bottom, and the bottom of the cylindrical portion is joined with the top of the inverted truncated conical bottom; disposable culture bags arranged in the inner cavities of the culture vessels and used for accommodating culture solution, wherein each disposable culture bag is provided with a multifunctional cover plate, and the multifunctional cover plate is connected to the top of the culture bag to seal the culture bag, and is provided with a plurality of connection holes leading to interior of the disposable culture bag; and a control system, wherein the control system controls the oscillating motion of the oscillator and parameters of the culture solution in the disposable culture bags.

The invention relates to a bioprocessing system having a main line (2) for conduction of a main flow (3) of a liquid, in particular biological, medium (45), having a main flow pump (5) for generation of the main flow (3) and having a system part (46) connected to the main line (2). What is proposed is that the bioprocessing system (1) comprises a powder transfer system (8) for metered delivery, in particular dust-free metered delivery, of an additive (47) and a feed line (9) which is connected to the powder transfer system (8) and which opens into the main line (2) at a feed point (10) and which comprises a return flow preventer (11) for prevention of a return flow of liquid medium (45), that the powder transfer system (8) feeds the additive (47) into the feed line (9) in powder form and drives it toward the feed point (10) by means of a pressurized transport gas (12) and that at least some of the fed additive (47) is input into the liquid medium (45) within the main line (2) downstream of the feed point (10) before the liquid medium (45) enriched with the additive (47) passes through or reaches the system part (46) connected to the main line (2).

This disclosure relates to equipment utilized to manufacture chemical agents, particularly biopharmaceuticals, using Disposable Containers (DCs).