The apparatuses described herein relate to preparation of a meat product. Apparatuses, systems comprising the apparatuses, and methods of making and use the systems and apparatuses are described herein. These are useful for controlling one or more of growth on and separation of a meat product from an enclosed substrate. The apparatuses and systems are configured to receive fluid and grow the meat product and/or separate the meat product from the substrate in a scalable manner.

A control unit includes a first connector configured to connect a proportional pressure regulator to a positive pressure supply and a second connector configured to connect the proportional pressure regulator to a negative pressure supply. The control unit further includes at least one sensor configured to detect an amount of air flow (volume per unit of time), positive or negative, within an air flow line connected to an output of the proportional pressure regulator, and a third connector configured to connect the air flow line to an air side of a diaphragm. Additionally, the control unit includes a controller programmed to control at least an opening and closing function of the proportional pressure regulator to attain a desired amount of air flow (volume per unit of time), positive or negative, within the air flow line.

A control unit includes a first connector configured to connect a proportional pressure regulator to a positive pressure supply and a second connector configured to connect the proportional pressure regulator to a negative pressure supply. The control unit further includes at least one sensor configured to detect an amount of air flow (volume per unit of time), positive or negative, within an air flow line connected to an output of the proportional pressure regulator, and a third connector configured to connect the air flow line to an air side of a diaphragm. Additionally, the control unit includes a controller programmed to control at least an opening and closing function of the proportional pressure regulator to attain a desired amount of air flow (volume per unit of time), positive or negative, within the air flow line.

This cell production device comprises: a cell production plate that includes a fluid circuit in which a plurality of functional sites are integrated; and a closed type connector that connects the fluid circuit to an external space in a closed manner, wherein the fluid circuit comprises, as the plurality of functional sites, an injection and discharge unit that injects or discharges a fluid into or out of the fluid circuit via the closed type connector, a variable volume unit that stores a fluid that is extruded or withdrawn by the injected or discharged fluid, and a cell induction and culture unit that performs at least one of induction and culture of cells based on the injected fluid.

A sensing cell culture vessel having one or more sensors on or in the vessel is configured to collect readings of various parameters or characteristics of a cell culture located within the sensing cell culture vessel and transmit the readings. The sensing cell culture vessels may be accompanied by a sensing plate having means for reading the one or more sensors and transmitting the one or more sensors to a server hosting electronic lab notebook for analyzing and storage of the readings. Sensing plates may further be equipped with cameras for imaging cell cultures located in the sensing cell culture vessels and transmitting the images to the server hosting the electronic lab notebook for analyzing and storage of the images. Embodiments of the invention allow for the continuous and automatic monitoring of cell cultures.

The invention discloses a first connection unit having a plurality of sensor surfaces and which is adapted to be asepetically connected to a second connection unit mounted e.g. on a flexible bioreactor bag.

A method for separating motile organisms from other organisms. The method comprises controlling a fluid delivery unit to provide a fluid flow to a sample separating device (302). The fluid flow has a sample introduction flow velocity set so that a sample may be introduced into a sample introduction zone of the device. The sample introduction flow velocity is sufficiently high such that an organism in the sample is unable to exit the sample introduction zone. The method comprises controlling the fluid delivery unit to reduce the fluid flow velocity from the sample introduction flow velocity to an operational flow velocity lower than the sample introduction flow velocity (303). The operational flow velocity is selected such that motile organisms in the sample are able to swim against the fluid flow and enter a sample collection zone of the device.

A method of cultivating algal cells of an algae belonging to a class selected from Chlorophyceae, Euglenophyceae, Bacillariophyceae and Haptophyceae includes: irradiating the algal cells with an artificial light having a ratio of (i) photon flux density in a wavelength range of 520-630 nm to (ii) photosynthetic photon flux density, that is 65% or more; and measuring a cell size of the algal cells. Irradiation and non-irradiation of the algal cells with the artificial light are switched, or the photon flux density in the wavelength range of 520-630 nm is changed, according to the measured cell size.

A multi-chamber single-use bioreactor for cell culture expansion has bag assembly and a rigid support structure defining a bag receiving space. The bag assembly disposed in the bag receiving space of the rigid support structure and supported by the rigid support structure. The bag assembly has at least a first flexible bag and a second flexible bag. The first bag defines a first reaction chamber, and the second bag defines a second reaction chamber. The first reaction chamber has a first volume, a first inlet, and a first outlet, and the second reaction chamber has a second volume different from the first volume, a second inlet, and a second outlet. The second inlet of the second bag is fluidically connected to the first outlet of the first bag so liquid in first reaction chamber can be transferred to the second reaction chamber.

The invention relates to a method for culturing and detecting microorganisms, comprising the steps of providing a liquid sample (S) in a barrel (10) of a device (1) for culturing and detecting microorganisms, passing the liquid sample (S) through a first filtering membrane (40) such that microorganisms contained in the liquid sample (S) are retained at a first side (41) of the first filtering membrane (40), contacting said first side (41) with a first growth medium (210) capable of supporting growth of microorganisms, incubating the first filtering membrane (40) and the first growth medium (210) at an incubation temperature, arranging a sensing surface (51) of a gas sensor (50) in fluid connection with a second side (42) of the first filtering membrane (40), detecting a metabolic gas released by the microorganisms by means of the gas sensor (50). The invention further relates to a device (1) for culturing and detecting microorganisms, comprising a barrel (10) enclosing a barrel compartment (13) for receiving a liquid sample (S), a first piston (20) which (20) is movable in said barrel (10), wherein said barrel compartment (13) is configured to be brought in fluid communication via a first filtering membrane (40) with a sensing surface (51) of a gas sensor (50) configured to detect a metabolic gas released by microorganisms, wherein the first filtering membrane (40) is configured to retain microorganisms contained in the liquid sample (S) at the first side (41) of the first filtering membrane (40). Furthermore, a sensor cartridge (4) and a kit of parts comprising the device (1) are provided.