A supporting material for an algal growth system includes a flexible sheet material configured to facilitate growth of a biofilm. The flexible sheet material is configured to be mounted on a first frame in a first mounted geometry, the flexible sheet material having a substantially vertical orientation when mounted on the first frame such that a first height of the first mounted geometry is greater than a first width of the first mounted geometry, the flexible sheet material being configured to be in contact with a contacting liquid.

An algal growth system includes a first flexible sheet material mounted on a first frame in a first mounted geometry having a first height and a first width, the first height being greater than the first width, and a second flexible sheet material mounted on a second frame in a second mounted geometry having a second height and a second width, the second height being greater than the second width. The first flexible sheet and the second flexible sheet material are noncontiguous. The algal growth system also includes a motor, the motor being coupled with an actuator system, where the motor actuates the actuator system, and a reservoir.

The present disclosure relates to methods for control of cell growth rates where cell growth is measured in situ. The methods are applicable to bacterial cells, mammalian cells, non-mammalian eukaryotic cells, plant cells, yeast cells, fungi, and archea.

The present disclosure relates to methods for control of cell growth rates where cell growth is measured in situ. The methods are applicable to bacterial cells, mammalian cells, non-mammalian eukaryotic cells, plant cells, yeast cells, fungi, and archea.

According to one embodiment of the present disclosure, a cell culture system includes: a cell culture container; a liquid storage part configured to store a liquid including a culture medium or a reagent to be supplied to the cell culture container; and a cell collection part configured to collect cells cultured in the cell culture container, wherein the cell culture container, the liquid storage part, and the cell collection part are connected by spatially closed-system lines at least during a period from feeding of the liquid to the cell culture container to removal of the cultured cells, and wherein the cell culture container is arranged in an incubator in a form of a multistage shelf including a liquid supply/discharge port.

The present disclosure relates to methods for control of cell growth rates where cell growth is measured in situ. The methods are applicable to bacterial cells, mammalian cells, non-mammalian eukaryotic cells, plant cells, yeast cells, fungi, and archea.

An algal growth system includes a first flexible sheet material mounted on a first frame in a first mounted geometry, the first flexible sheet material having a substantially vertical orientation when mounted on the first frame such that a first height of the first mounted geometry is greater than a first width of the first mounted geometry. The algal growth system also includes a first drive shaft coupled with the first frame, an actuator system coupled with the first drive shaft, a motor coupled with the actuator system. The motor actuates the actuator system and the first drive shaft such that the first flexible sheet material is actuated. The algal growth system also includes a liquid source consisting of a dripper or a mister. The liquid source is configured to direct a contacting liquid to the first flexible sheet material.

The present disclosure relates to methods for control of cell growth rates where cell growth is measured in situ. The methods are applicable to bacterial cells, mammalian cells, non-mammalian eukaryotic cells, plant cells, yeast cells, fungi, and archea.

The present invention is a kit to be used for obtaining Adipose tissue-based stem cells, which especially is suitable for obtainment of Adipose tissue-based stem cells, which comprises a reservoir (1) through which the entrance of the adipose tissue, that is taken from a predetermined area of the individual, into the kit; characterized by comprising a first housing (2), which is located on the said reservoir (1) and enables the transmission of the adipose tissue into the kit, a second housing (3), which is located on the said reservoir (1) and which enables the second injector (40) to be positioned outside the reservoir (1) and in a perpendicular position to the reservoir (1), a third housing (4) which enables the third injector (50) to be positioned outside the reservoir (1) and in a perpendicular position to the reservoir (1), an empty body (6) which is fixed inside the reservoir (1), a first inlet (7) which enables the transmission of the adipose tissue into the body (6) by pushing of the injector, a passage (8) which can rotate its own axis and which enables the circulation of the adipose tissue that is inside the body (6) between a desired inlet inside the body (6) and another inlet which is positioned in a 90 degree angle to this inlet by this rotation movement, at least one cover (10) which enables the said movement of the passage (8) and covers the top of the reservoir (1), a second inlet (12) which comprises a first splitting element (11) that is obtained by alignment of a multiple of cutting elements (10), and a third inlet (14) which comprises at least one second splitting element (13) which enables the adipose tissue split when it enters to and exits from the injector and is obtained by alignment of a multiple of cutting elements (10).

An algal growth system can include a frame and a flexible sheet material that can have a substantially vertical orientation, where the flexible sheet material can be configured to facilitate the growth and attachment of algae, where the flexible sheet material can be supported by the frame. The algal growth system can include a first drive shaft, where the first drive shaft can be coupled with the frame, where the first drive shaft can support and actuate the flexible sheet material, a gear system, where the gear system can be coupled with the first drive shaft, a first roller, where the first roller can be coupled with the frame and can be configured to guide the flexible sheet material, and a drive motor, where the drive motor can be coupled with the gear system, where the drive motor can actuate the gear system and the at least one drive shaft such that the flexible sheet material can be actuated.