A single-use bioreactor is provided. The single-use bioreactor may include a bioprocess container, a shell, at least one agitator, at least one sparger, at least one gas filter inlet port for the sparger(s) and headspace overlay, at least one fill port, at least one harvest port, at least one sample port, and at least one probe. In examples, at least one controller may monitor and control one or more parameters associated with the single-use bioreactor A method to cultivate and propagate mammalian cells is also provided. The method may include cultivating under suitable conditions and in a suitable culture medium in a first single-use bioreactor, transferring the medium containing the cells obtained by propagation from the at least one mammalian cell is into a second single-use bioreactor, transferring the medium containing the cells obtained by propagation from the at least one mammalian cell is into a third single-use bioreactor, and cultivating the cells in the third bioreactor.

Disclosed is a photosynthetic culture production device including at least one photo-bioreactor chamber having a supply/discharge unit, and including: an aqueous liquid containing a photosynthetic culture; at least one unit for supplying and discharging fluids from the chamber interacting with a management system; at least one light distributor including at least one first wall arranged so as to receive the light at a proximal end, at least one second wall arranged so as to emit at least part of the received light, and a sealed cavity defined by the at least one first wall and the at least one second wall, part of the emitting wall being immersed in the aqueous liquid containing the photosynthetic culture; at least one fluid partially filling the sealed cavity; and a cover, limiting evaporation. The cover has at least one opening, keeping the at least one light distributor stationary in the chamber.

A sample holder (10) comprises a sample chamber (33), a gas reservoir (32) and an upper layer (20) covering over the sample chamber (33) and gas reservoir (32), wherein a bottom surface of the upper layer (20) comprises a microstructure array (23) which overlies at least a portion of a top periphery of the sample chamber (33), and wherein the microstructure array (23) is in communication with a gas path which extends to the gas reservoir (32), to allow gas exchange between the sample chamber (33) and the gas reservoir (32).

An organomimetic device includes a microfluidic device that can be used to culture cells in its microfluidic channels. The organomimetic device can be part of dynamic system that can apply mechanical forces to the cells by modulating the microfluidic device and the flow of fluid through the microfluidic channels. The membrane in the organomimetic device can be modulated mechanically via pneumatic means and/or mechanical means. The organomimetic device can be manufactured by the fabrication of individual components separately, for example, as individual layers that can be subsequently laminated together.

The present disclosure provides a bioreactor for cell processing. The bioreactor comprises a container including a base section comprising a sensor window chosen from a transparent sensor window or a translucent sensor window, a top section arranged opposite to the base section and comprising a fluid inlet and a fluid outlet, and a sidewall extending between the base section and the top section and defining an internal volume of the container adapted to hold a cell suspension. At least one optical element disposed on the sensor window within the internal volume, the at least one optical element adapted to emit a fluorescence signal in response to incident light, the fluorescence signal associated with one or more parameters of the cell suspension.

The present invention relates to cell culture in bioreactors, such as flexible cellbag bioreactors. More closely the invention relates to a method and system for determining the cell density in a bioreactor culture and for controlling the perfusion rate of a suspension culture of cells in a bioreactor, comprising measuring the oxygen uptake of primary mononuclear cells in a non-static bioreactor.

An assemblable appliance and method of recycling organic waste into biogas and liquid fertilizer, implementing essentially anaerobic digestion processes, is described. The assemblable appliance includes: a pliant structured exoskeletal envelope, pliable collapsible anaerobic digester and gas tank. A compact kit-of-parts for assembling the aforementioned appliance and respective method using the aforementioned appliance for recycling organic waste into biogas and liquid fertilizer are described.

Disclosed herein is a single use continuous recovery, flow-through harvest vessel and corresponding method for harvesting culture medium and simultaneously either leaving the microcarrier beads behind in the vessel or flowing microcarrier beads and medium back into a bioreactor.

A system for oxygenating a biological culture includes a container bounding a compartment and having a top wall, a bottom wall, and an encircling sidewall extending therebetween; a tubular member projecting into the compartment of the container and terminating at a terminal end; a gas supply coupled with the tubular member and being configured to blow gas through the tubular member; and a mixing element disposed within compartment of the container at a location between the terminal end of the tubular member and the bottom wall of the container, the mixing element being configured to mix the liquid.

A flow distribution device for bioprocess systems, comprising: a flow distribution manifold (12; 112) comprising: at least four fluid connection conduits (14), wherein each fluid connection conduit (14) comprises a first end (18) for fluid connection and an opposite second end (20), and wherein at least three of the fluid connection conduits comprise a membrane (19a) and a valve seat (19b), which membrane (19a) can be put in at least two different positions in relation to the valve seat (19b) for allowing or preventing fluid flow between the first end (18) and the second end (20) of the fluid connection conduit (14); and a central common compartment (30) to which the second ends (20) of each of the fluid connection conduits (14) are connected, whereby the first ends (18) of each of the fluid connection conduits (14) can be in fluid communication with the central common compartment (30) and wherein the fluid connection conduits (14) are entering the central common compartment (30) from at least three different directions; wherein said flow distribution device (10) further comprises at least three membrane actuation members (41) which are provided in connection with one membrane (19a) of the flow distribution manifold (12; 112) each, wherein each of said membrane actuation members (41) is configured for actuating the membrane (19a) to be in at least two different positions in relation to the valve seat (19b), wherein a first position of the membrane (19a) allows flow between the first end (18) and the second end (20) of the fluid connection conduit (14) and a second position of the membrane (19a) prevents flow between the first end (18) and the second end (20) of the fluid connection conduit (14).