A device for mechanically stabilizing a sensor port on a flexible bag including a rigid, substantially plate-shaped support part, which has a receptacle for a rigid connecting part integrated in the bag, in particular a sensor, and a holding mechanism on the receptacle. The device further includes a fastening element adapted to be attached to the holding mechanism of the support part such that it fixes the support part to the connecting part. The device may include a rigid support part which can be assembled from at least two parts, preferably struts. The parts surround a free area or an opening in which a rigid connecting part integrated in the bag can be placed. In an assembled state of the parts, the free area or the opening has a smaller diameter than the connecting part, so that the parts form a load-receiving mechanism for the connecting part.

The present invention provides novel devices, systems and methods for cultivating macroalgae in a waterbody, more particularly in the sea/offshore.

A microplate assembly for a plurality of samples includes a donor microplate having a plurality of sample donor cavities. The microplate assembly further includes a receiver microplate having a plurality of sample receiver cavities each sample receiver cavity having a transparent receiver bottom configured to enable microscopic imaging. In addition, the microplate assembly includes a leak-tight connecting structure configured to assemble the donor microplate and the receiver microplate, with at least one of the sample donor cavities being in communication with at least one of the sample receiver cavities. Further aspects are a receiver microplate and a leak-tight connecting structure for a microplate assembly as well as a method for transferring samples by means of a microplate assembly.

A device for seeding cells includes a container with a wall, a bottom and a lid. The wall extends between the bottom and the lid. The container can be equipped to be loaded with cells, in particular with cells form a cell suspension. The container defines a rotation axis. The device is further equipped to rotate the container around the rotation axis. The container includes a structured surface that can be arranged at the inner surface of the container. The structured surface has structures equipped to receive the cells. The rotation exerts a (g-)force in direction of the structured surface, such that the g-force acts perpendicular to the structured surface. The exerted force in the direction of the structured surface resembles a g-force required for sedimentation of the cells into the structures.

An incubator system includes an incubator unit including incubator chamber defined by chamber walls formed of a non-magnetic material; a control unit physically separated from the incubator unit and including operational controls for operation of the incubator system; and at least one duct coupling the incubator unit to the control unit, wherein the incubator system is configured so that the incubator chamber experiences a magnetic field variation of no more than 100 nT arising from the incubator system during incubation operation of the incubation system.

The invention relates to an apparatus (100) for determining properties of a sample (110) arranged in at least one receptacle (130) of a container device (120). The apparatus (100) comprises an actuator (30) which is configured to be coupled to the sample (110) via at least one holding element (34) which is configured to hold the sample (110). Further, the actuator (30) is configured to apply a mechanical stimulus to the sample (110) via the at least one holding element (34). The apparatus (100) comprises a force sensing device (20) which is configured to be coupled to the sample (110) via at least one cantilever (22). Further, the apparatus (100) comprises a frame (1), wherein the actuator (30) and the force sensing device (20) are configured to be mounted to the frame (1), and wherein the frame (1) is configured to be arranged on the container device (120). When the actuator (30) and the force sensing device (20) are mounted to the frame (1) the at least one holding element (34) and the at least one cantilever (22) are arranged in the at least one receptacle (130) when the frame (1) is arranged on the container device (120).

A segmented culture dish and imprinting system allows duplicate plates to be produced rapidly and without culture-to-culture overlap. The segmented culture dish and imprinting system includes a dish stamp, a first culture dish, and a second culture dish. The dish stamp may be placed on the first and/or the second culture dishes. The first and the second culture dishes have a key on an inside surface that ensures the orientation of cultures is always preserved, eliminating the need for markings on culture dishes.

A plurality of caps are provided each with a visual coding of color and/or indicia for use with different sizes of bottles at least in accordance with a height of the bottles from a closed bottom end to an open top end for engaging each of the caps. Each of the caps has a tube mounted to, or through, an aperture extending through a top closed end of the cap to extend a selected length enabling one end of the tube to reach or extend along an interior surface of the bottom end of any of the bottles of the height to which the cap is coded for use therewith. The other end of tube is extendable to a bioreactor container. Each of the caps has another tube or port to another aperture of the cap to provide an air vent with an optional air filtering device.

Bioreactor and production process of adherent cell cultures that uses the bioreactor. The bioreactor includes a recipient with a cover, and further includes internally a bracket from which protrudes at least one tray that supports a three-dimensional polymer-based element mounted on it, such that when the bioreactor is filled with a culture medium the at least one tray and the three-dimensional polymer-based element are surrounded by the culture medium.

The process includes the following steps: the bracket, with the at least one tray of the bioreactor, with a three-dimensional polymer-based element is immersed in the culture medium, cells that are desired to be planted on the three-dimensional polymer-based element are inoculated from outside the bioreactor, and the culture is left in the bioreactor so that the cellular proliferation is produced.

Methods and apparatus of bioreactors for therapeutic cells manufacturing are provided herein. In some embodiments, a bioreactor includes: an upper bioreactor reservoir configured to perform multiple cell therapy manufacturing process steps including genetic modification and expansion to a plurality of cells disposed therein, wherein the upper bioreactor reservoir includes a plurality of ports for delivering fluids into and out of the upper bioreactor reservoir; a lower bioreactor compartment configured to hold a suspension comprising a molecular species; and a membrane disposed between the lower bioreactor compartment and the upper bioreactor reservoir, wherein the membrane includes a plurality of micro-straws extending through the membrane and into the upper bioreactor reservoir to transfect the plurality of cells with the molecular species.