Xenograft egg models comprising a fertilized non-mammalian egg comprising an ablated immune system, a first plurality of mammalian cells and a second plurality of mammalian cells, wherein the second plurality comprises immune cells are provided. Methods of producing the xenograft egg model as well as using the xenograft egg model for screening are also provided.

Structures and methods for tissue engineering include a multicellular body including a plurality of living cells. A plurality of multicellular bodies can be arranged in a pattern and allowed to fuse to form an engineered tissue. The arrangement can include filler bodies including a biocompatible material that resists migration and ingrowth of cells from the multicellular bodies and that is resistant to adherence of cells to it. Three-dimensional constructs can be assembled by printing or otherwise stacking the multicellular bodies and filler bodies such that there is direct contact between adjoining multicellular bodies, suitably along a contact area that has a substantial length. The direct contact between the multicellular bodies promotes efficient and reliable fusion. The increased contact area between adjoining multicellular bodies also promotes efficient and reliable fusion. Methods of producing multicellular bodies having characteristics that facilitate assembly of the three-dimensional constructs are also provided.

Devices, systems, and methods can be used for the automated production of dendritic cells (DC) from dendritic cell progenitors, such as monocytes obtained from peripheral blood. The invention makes it possible to obtain sufficient quantities of a subject's own DC for use in preparing and characterizing vaccines, for activating and characterizing the activation state of the subject's immune response, and to aid in preventing and/or treating cancer or infectious disease.

Embodiments herein provide methods of differentiating neural stem cells to neuronal cells while concomitantly retarding neural stem cell proliferation. Resultant cultures demonstrate reduced clumping of cells, increased purity of neuronal cells and accelerated electrophysiology as compared to control methods.

The present disclosure describes a microfluidic chip for culturing and in vitro testing of 3D organotypic cultures. The tests may be performed directly on the organotypic culture in the microfluidic chip. The microfluidic chip includes at least one microfluidic unit which includes two fluidic compartments, such as upper and lower, separated by a permeable supporting structure, one or more access opening for the fluidic compartments, and a set of lids interchangeable with a set of insets. The permeable support structure serves as a support for the organotypic culture. The upper and lower compartments may include inlets and outlets which allow fluids to be perfused into the lower compartment and fluids to be perfused into the upper compartment. The access opening may be closed with a lid or accommodate an inset.

The purpose of the invention is to provide novel cell culture substrates, cell culture vessels, and methods for cell culture. A cell culture substrate having a planar mesh structure, the substrate being coated with a polymer, is provided. Cells are cultured in a cell culture vessel having this substrate.

Disclosed are a spheroid array and more particularly, a droplet trapping structure array capable of isolating all or selected spheroids into an isolated droplet array environment and the use thereof. The droplet-trapping structure array and the method and device for transferring spheroids using the same have the advantages of transferring droplets or spheroids with very high efficiency and very small variation between users by simply contacting two arrays. The spheroid transfer method and device enable mass-production of spheroid arrays in an isolated environment. In particular, the droplet trapping structure array and the spheroid transfer method can be useful for the treatment of spheroids with various reagents and the exchange of culture media.

A drug screening platform simulating hyperthermic intraperitoneal chemotherapy including a dielectrophoresis system, a microfluidic chip and a heating system is disclosed. The dielectrophoresis system is used to provide a dielectrophoresis force. The microfluidic chip includes a cell culture array and observation module and a drug mixing module. The cell culture array and observation module are used to arrange the cells into a three-dimensional structure through the dielectrophoresis force to construct a three-dimensional tumor microenvironment. The drug mixing module is coupled to the cell culture array and observation module and used to automatically split and mix the inputted drugs and output the drug combinations into the cell culture array and observation module. The heating system is used for real-time temperature sensing and heating control of the drug combinations on the microfluidic chip to simulate high-temperature drug environment when performing hyperthermic intraperitoneal chemotherapy on the three-dimensional tumor microenvironment.

The present invention relates to cell culture media comprising 5-Thio-L-fucose and the use of 5-Thio-L-fucose for modulating the glycosylation profile of antibodies or other Fc containing proteins and thereby modulating the binding affinity of said proteins.

The present invention relates to cell culture media comprising 5-Thio-L-fucose and the use of 5-Thio-L-fucose for modulating the glycosylation profile of antibodies or other Fc containing proteins and thereby modulating the binding affinity of said proteins.