A bag assembly for use with a heat exchanger includes a flexible bag having of one or more sheets of polymeric material, the bag having a first end that bounds a first compartment and an opposing second end that bounds a second compartment, a support structure being disposed between the first compartment and the second compartment so that the first compartment is separated and isolated from the second compartment. A first inlet port, a first outlet port, and a first drain port are coupled with the flexible bag so as to communicate with the first compartment. A second inlet port, a second outlet port, and a second drain port are coupled with the flexible bag so as to communicate with the second compartment.

An inverted conical bioreactor is provided for growing cells or microorganisms. The bioreactor has an internal space and a perforated barrier within the vessel, through which a liquid may flow, where cells or microorganisms cannot pass through the perforated barrier. The perforated barrier divides the internal space of the bioreactor into a first chamber and a second chamber. Cells are grown within the second chamber and can be perfused by re-circulating the liquid, for example a growth medium, through the bioreactor. Various inlet ports and outlet ports allow controlling the parameters of flow of the growth medium.

Improved cell culture devices and related methods that overcome the limitations of prior devices and methods, by creating devices that can integrate a variety of novel attributes. These various attributes include the use of gas permeable material and medium volumes that exceed conventional devices as well as compartments that can facilitate the long term study of high density cultures with reduced disruption of the culture environment, the ability to study the migration of items of interest including substances such as chemokine, track the movement of cells, and monitor cell to cell interactions.

A cell culture analyzer comprises a stirring member and an air discharge and intake unit. The stirring member is used in a state of being immersed in a medium, and has a liquid discharge and intake port for discharging or drawing in the medium, and an air discharge and intake port for discharging or drawing in air in order to discharge or draw in the medium from the liquid discharge and intake port. The air discharge and intake unit is linked to the air discharge and intake port of the stirring member, and discharges or draws in the air discharged or drawn in from the air discharge and intake port.

A culture container (1) having a guide thread (31) and a plurality of cells (32) that is capable of culturing a regenerative hair follicle germ (30), wherein the culture container (1) is equipped with a first recess (10) and a second recess (20) and the second recess (20) has a second bottom (22) where the guide thread (31) can be positioned in the center of an opening (23) and a method for producing a regenerative hair follicle germ that includes a step for aggregating a cell population including epithelial cells (32a) within the second recess (20) of the culture container (1), a step for aggregating a cell population including mesenchymal cells (32b) within the second recess (20), a step for inserting the guide thread (31) into the second recess (20), and a step for culturing the cell population including epithelial cells (32a) and the mesenchymal cells (32b).

The present disclosure provides a system, including methods and apparatus, for culturing, monitoring, and/or analyzing organoids. In an exemplary method of organoid culture, the method may comprise disposing a scaffold in a receptacle having an open side. A sealing member may be bonded to the open side of the receptacle to create a chamber. An organoid may be formed in the chamber using the scaffold. Fluid and/or at least one substance may be introduced into the chamber from an overlying reservoir for contact with the organoid.

Provided are sealable transport incubators for uniform incubation of sample specimens (e.g., microbial samples) during transport between two locations (e.g., microbial sampling and detection locations, the incubators comprising a multi-slot thermal-transfer divider each in uniform thermal communication with a heat source (e.g., electrical or phase change materials (PCM), and configured to provide for uniform heat transfer and distribution to the sample specimen during transport in the transport incubator. Additionally provided are methods for expediting provision of microbial assay detection results (e.g., using the disclosed sealable transport incubators).

The present invention provides improved devices for co-culture of cells. The devices include inserts having invertible wells that can be lowered into a well of any standard cell culture plate. A first population of cells can be cultured in the invertible wells of the inserts and a second population of cells can be cultured in the wells of a cell culture plate. Once the first population of cells attach to the invertible wells, the inserts are flipped over and placed into the wells of the cell culture plate to co-culture with the second population of cells.

The systems and methods of the present disclosure provide highly deformable porous membrane culture systems and actuation methods for studying the effects of biomedical stretch on cultured tissue. A well plate can include a well having a first opening configured to receive an insert coupled to a deformable membrane. The well plate can include a gasket positioned within the well and configured to create a seal between the insert and the well when the insert is positioned in the well. The well plate can include a chamber defined beneath the well, the chamber configured to receive fluid media and to expose the fluid media to a surface of the deformable membrane when the insert is positioned in the well. The well plate can include an actuator configured to stretch the deformable membrane by a target amount of strain.

Example embodiments include 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 that go through a basal chamber arranged under an apical chamber. The apical and basal chambers are separated by a porous membrane. The basal chamber has a bottom part arranged higher than a bottom part of each of the culture medium reservoirs. The culture model comprises further a cavity under at least the bottom part of the basal chamber and at least one means for capturing at least one image from a bottom and/or top of the at least one cell culture module.