A method of manufacturing a composite sensor assembly includes: providing a port including a high surface tension thermoplastic, the port having a hollow tubular portion and a base having a polymer surface; fusing the polymer surface of the port to a wall of a polymeric bioprocess vessel so that the port communicates with an opening in the wall; and retaining a sensor unit within the hollow tubular portion of the port with an adhesive, at least a portion of the sensor unit being polymeric, wherein the port provides the sensor unit access to an interior of the polymeric bioprocess vessel.

A bioreactor includes a base and a lid. The base includes two opposing curved or convoluted surfaces, two opposing flat surfaces, a window disposed on one of the flat surfaces, the window having a higher degree of transparency compared to other portions of the base, wherein images or videos of cells are captured through the window by non-invasive ISM device, and a rounded bottom. The lid is attachable to the base. The lid includes a shaft and a semipermeable membrane attached to the shaft, the semipermeable membrane being permeable to oxygen but impermeable to viruses and bacteria. The PAT-based online analysis directs the adaptive manipulations of bioreactor towards efficient, automated, and GMP-compliant clinical protocols of cell culture.

An automated cell culturing device, which expands, detaches and prepares cells, ready to be implanted in vivo is disclosed. The device is composed by a multi-layered cell culture chamber, a cell preparation chamber, and critical parameters control units which automatically drive the cell culture medium circulation, change and refill. The device according to the invention is characterized in that all the components contacting cells and culture medium constitute a totally disposable “cartridge” in order to avoid cross-contamination and improve safety. The device is particularly useful for expanding and preparing mesenchymal stem cells for osteoarthritis (OA) therapy, and for other cell based therapies in mammals.

An incubation device has multiple rocking platforms with each platform pivotally mounted about a respective axis. Each rocking platform has a respective receiving device for mechanically reversibly receiving a respective incubation channel. The device also has a common drive unit for common respective rocking movements of each platform from a zero position through with a specific angle range as a result of movement of the drive unit. Each rocking platform is coupled to the drive unit via a respective coupling mechanism, and each coupling mechanism elastically and resiliently couples the respective rocking platform to the drive unit, such that when the rocking platform is restrained, despite continuation of the drive movement, the rocking platform remains motionless in a fixed position. After release of the restraint on the rocking platform, the rocking platform resumes the rocking movement with the specific angle range.

A system for controlling a motion of a cell culture includes a tray adapted to hold a cell culture, a camera adapted to capture an image of the cell culture, and a device adapted to control a movement of the tray. The system also includes a processor adapted to determine a first movement of the tray, receive from the camera data representing an image of the cell culture, determine a characteristic of the cell culture based on the image data, determine a second movement of the tray based on the characteristic, the second movement being different from the first movement, and cause the tray to move in accordance with the second movement.

Methods, systems, and apparatus for cultivating cells in media-exchanging wells. In an exemplary method of cell cultivation, a device (50) may be selected that includes a row of wells (52), and a first reservoir (56) and a second reservoir (58) located at opposite ends of the row of wells (52). Each well (52) may have a lower portion and an upper portion. The lower portion of each well (52) of at least two of the wells (52) may contain a cell culture in contact with a liquid. Liquid may be transferred between the first reservoir (56) and the second reservoir (58) at least partly along a flow path (62) defined by the device and extending through the upper portion of each well (52) of the row of wells (52), such that molecules of the media are exchanged between or among the at least two wells (52).

When detachment of a cell sheet from a culture dish has started at an unintended timing, immediately detach the cell sheet from the culture dish while preventing generation of wrinkles and the like in the cell sheet. A cell culture device captures an image of cells in the culture dish, and controls a cooling mechanism and a shaking mechanism based on the image so as to shake the cells while cooling them.

The described invention provides an ex vivo dynamic multiple myeloma cancer niche contained in a pumpless perfusion culture device. The dynamic multiple myeloma cancer niche includes (a) a three-dimensional tissue construct containing a dynamic ex vivo bone marrow niche, which contains a mineralized bone-like tissue containing viable osteoblasts self-organized into cohesive multiple cell layers and an extracellular matrix secreted by the viable adherent osteoblasts; and a microenvironment dynamically perfused by nutrients and dissolved gas molecules; and (b) human myeloma cells seeded from a biospecimen composition comprising mononuclear cells and the multiple myeloma cells. The human myeloma cells are in contact with osteoblasts of the bone marrow niche, and the viability of the human myeloma cells is maintained by the multiple myeloma cancer niche.

The present invention provides a shake-type culture apparatus which can perform large scale culture without using stirring blades and a culture method using the same. More particularly, there are provided a shake-type culture apparatus comprising: a culture bag made from a soft packaging material; an outer shell container being arranged to house the entirety of the culture bag to be able to perform adjustment of a temperature thereof; and a power source for shaking the outer shell container housing the culture bag, wherein the contents in the culture bag can be stirred and mixed by shaking the outer shell container housing the culture bag; and a culture method using the same.

Systems and methods of testing a fluid sample are provided. A method can include controlling an orientation of a loader including a sample holder configured to hold a sample vessel to correspond to a first predetermined tilt angle. The method can include controlling an articulator to transfer the fluid sample from the sample vessel to at least one well of a plurality of wells of a multiwell plate positioned on a plate deck within the enclosure. The method can include controlling the articulator to move the multiwell plate to a hotel incubator within the enclosure. The method can include applying a bacteriophage to the fluid sample. The method can include controlling the articulator to move the multiwell plate from the hotel incubator to a testing system within the enclosure after a predetermined reaction time period. The method can include receiving output data from the testing system.