Embodiments described herein generally provide for the expansion of cells in a cell expansion system using an active promotion of a coating agent(s) to a cell growth surface. A coating agent may be applied to a surface, such as the cell growth surface of a hollow fiber, by controlling the movement of a fluid in which a coating agent is suspended. Using ultrafiltration, the fluid may be pushed through the pores of a hollow fiber from a first side, e.g., an intracapillary (IC) side, of the hollow fiber to a second side, e.g., an extracapillary (EC) side, while the coating agent is actively promoted to the surface of the hollow fiber. In so doing, the coating agent may be hydrostatically deposited onto a wall, e.g., inner wall, of the hollow fiber.

An apparatus for cell cultivation includes first reservoir structure, second reservoir structure and a membrane. The first reservoir structure has first matrix of pitted reservoirs and the second reservoir structure has second matrix of pitted reservoirs. The first reservoir structure, second reservoir structure and the membrane are arranged as a stack. The membrane is arranged between first reservoir structure and second reservoir structure, and the first matrix of pitted reservoirs is aligned with the second matrix of pitted reservoirs to couple pitted reservoirs of the first matrix of pitted reservoirs together with pitted reservoirs, of the second matrix of pitted reservoirs via the membrane.

The present disclosure relates to a cell culture apparatus, methods for cell cultivation by using the cell culture apparatus, and a cell culture incubator comprising the cell culture apparatus. The cell culture apparatus comprises a plurality of cell culture modules arranged adjacent to each other. Each cell culture module comprises two or more culture medium reservoirs connected by two or more flow channels. The flow channels go through a basal chamber arranged under an apical chamber. The apical and basal chambers are separated by a porous membrane. The bottom part of the at least two culture medium reservoirs comprise a holding member configured to be compatible with a liquid handling system. The basal chamber has a bottom part arranged higher than a bottom part of each of the culture medium reservoirs. The cell culture apparatus further comprises a cavity under the bottom part of the basal chamber.

The present invention provides a cell culture apparatus. A cell culture apparatus according to one embodiment of the present invention is a cell culture apparatus for culturing a cell to form the cell into a three-dimensional spheroid. The cell culture apparatus may comprise: a plate; and a well which is arranged, in plural, on one side of the plate at predetermined intervals, has cells cultured inside, and has a micropattern disposed on the inner surface such that the inner surface and the cells are spaced apart from each other.

There is provided a microfluidic device (10) comprising a microfluidic structure having multiple spatially defined cell capturing channels (2) configured for enabling growth of cells or genetic libraries of cells or cell strains that are capable of producing or secreting compounds. The microfluidic structure of the microfluidic device (10) further comprises multiple spatially defined detection chambers (1; 1A) configured to receive and accommodate target entities. Each of the detection chambers (1) is configured for fluid connection with at least one of the cell capturing channels (2), and has a selective barrier (3A) defined between the detection chamber (1; 1A) and the respective cell capturing channel or channels (2) and adapted for allowing flow of at least one of the compounds from the respective cell capturing channel or channels (2) into the detection chamber (1; 1A) enabling the target entities in the detection chamber to be exposed to said at least one compound, while stopping cells or target entities from passing through the selective barrier (3A).

The present disclosure provides methods for generating megakaryocytes and novel platelet variants from the same CD34+ progenitor stem cells, which comprises at least two stages: stage zero (0) comprising an expansion and maintenance stage of the CD34+ progenitor stem cells for a period ranging between 0 hours to 48 hours; and, stage one (I) comprising a differentiation phase wherein the differentiation phase comprises differentiating the CD34+ progenitor stem cells in step (i) for a period sufficient to generate substantially matured megakaryocytes. Novel platelet variants are produced by passaging the megakaryocytes, produced by the CD34+ progenitor stem cells, through a bioreactor or a fluidic device. Formulations comprising megakaryocytes and platelet variants derived from CD34+ progenitor stem cells and methods of their use are also disclosed.

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).

Therapeutic extracellular vesicles (EVs) containing high copies of functional nucleic acids and other biomolecules are produced in large quantities by laying donor cells on a surface of a chip, adding various plasmids, other transfection vectors and their combinations to a buffer on the chip, applying a pulsulatic electric field across the cells laid on top of the chip surface and plasmids/vectors buffer solution below the chip surface, and collecting the EVs secreted by the transfected cells. The chip surface has a three-dimensional (3D) nanochannel electroporation (NEP) biochip formed on it, capable of handling large quantities of the donor cells. The buffer is adapted for receiving plasmids and other transfection vectors.

A method for displacing a fluid and simultaneously gas enriching a liquid cell culture medium with a gas. The method includes injecting a controlled volume of a gas or gas mixture into a one chamber by using a gas flow controller, the injection taking place through a gas inlet into a volume of liquid. This injection produces bubbling and agitation of the volume of liquid; a build-up of gas or gas mixture due to buoyancy in a hermetic space formed by the volume of liquid and the chamber, and a pressure increase in the chamber until a sufficient controlled pressure is reached of less than or equal to 10 bar. This increase displaces the volume of liquid by a fluid outlet connecting the volume of liquid to the exterior of the chamber. Also provided are a device implementing the method and a cell culture system in a multi-well culture plate.

In example implementations, an apparatus is provided. The apparatus includes a channel, a reagent chamber, a synthetic jet channel, and an energy source. The channel is to hold a cell. The reagent chamber is coupled to the channel and stores a reagent. The synthetic jet channel is coupled to the channel and the reagent chamber. The energy source is located in the synthetic jet channel to heat a liquid in the synthetic jet channel to create a synthetic jet that carries the reagent through towards the cell to inject the reagent into the cell.