A method of manipulating allogeneic cells for use in allogeneic cell therapy providing a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism, or Mirror Effect. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the mirror of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The mirror of the GVH effect is the host vs. graft (HVG) effect The anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect. The highly activated allogeneic cells of the invention can be used to stimulate host immunity in a complete HLA mis-matched setting in a patient.

The present invention features assays for co-culturing primary cells while maintaining key biological activities specific to the primary cells. The invention is based, at least in part, on the discovery that compositions and methods for primary cells in a high-throughput co-culture platform, image analysis for distinguishing cells in co-cultures and assays that are suitable for screening of agents in epithelial cells, such as hepatocytes.

Methods for treating radiation or chemical injury are described that comprise administering to a subject a therapeutically effective amount of adherent stromal cells. Methods of preparing adherent stromal cells and pharmaceutical compositions comprising the cells are also described.

A lattice structure for culturing cells in a bioreactor is effective for culturing high density cells and maintaining cell type homogeneity. The lattice structure includes a plurality of channels forming a set of channels, each of the plurality of channels extending between a first channel pore surface and a second channel pore surface and each of the plurality of channels having a first channel pore and a second channel pore altogether forming a plurality of channel pores on each of the first channel pore surface and the second channel pore surface, wherein each of the channel pores has an area of between about 0.01 mm.sup.2 to about 1 mm.sup.2, and wherein the lattice structure is made of a biocompatible rigid material having a Young's modulus value of at least 0.5 GPa.

The present subject matter provides a microfluidic device that enables the precise and repeatable three dimensional and compartmentalized coculture of muscle cells and neuronal cells. Related apparatus, systems, techniques, and articles are also described.

A bioreactor is provided herein. The bioreactor includes a vessel having a wall at least partially defining an interior compartment for receiving fluid, at least one port, and at least one cap configured to removably engage with the at least one port, the at least one cap comprising a filter material. A cell culture method is also provided herein which includes adding cells and cell growth medium to a vessel of a bioreactor and adding microcarriers to the vessel to form substantially confluent cells on the microcarriers. The cell culture method further includes washing the confluent cells, harvesting the confluent cells to form a solution containing the cells, and removing the solution containing the cells from the vessel by flowing the solution through a filter material in a cap removably engaged with at least one port of the bioreactor.

The present invention provides a culture method for culturing, in recesses (10), a population including two or more cells including a cell derived from a stem cell and a mesenchymal cell. The cell derived from a stem cell is a cell obtained by differentiating a stem cell in vitro. The cell is a cell of one or more types selected from the group consisting of an endodermal cell, an ectodermal cell, and a mesodermal cell. The population is cultured in the recesses (10) together with a vascular cell or a secretor factor. Each recess (10) includes a space in which cells are movable. When a volume of the space is represented by V mm.sup.3 and the number of mesenchymal cells seeded in the space is represented by N, V is 400 or less and N/V is in a range from 35 to 3000.

The subject invention concerns novel and translatable materials and methods for expansion of stem cells, such as mesenchymal stem cells (MSC), that significantly improve translational success of the cells in the treatment of various conditions, such as stroke. The subject invention utilizes cell self-aggregation as a non-genetic means to enhance their therapeutic potency in a microcarrier bioreactor. The subject invention integrates a cell aggregation process in a scalable bioreactor system. In one embodiment of the method, thermally responsive microcarriers (TRMs) are utilized in conjunction with a bioreactor system. Cells are cultured in a container or vessel in the presence of the TRMs wherein cells adhere to the surface of the TRMs. Once cells are adhered to the TRMs they can be cultured at a suitable temperature for cell growth and expansion, e.g., at about 37 C. After a period of time sufficient for cell growth and expansion on the TRMs, the cell culture temperature is reduced so that the cells detach from the TRMs. The detached cells are allowed to form cell clusters that are then cultured under conditions such that the clusters aggregate to form 3D aggregates. The 3D aggregates can be collected and treated to dissociate the cells (e.g., using enzymatic treatment, such as trypsinization). Dissociated cells can then be used for transplantation in methods of treatment or for in vitro characterization and study.

Disclosed are methods of preparing CD34+CD43+ hematopoietic progenitor cells (HPC) in vitro according to embodiments of the invention. Also disclosed are methods of differentiating CD34+CD43+ hematopoietic progenitor cells to hematopoietic lineage cells according to embodiments of the invention. Also disclosed are methods of treating or preventing a condition in a mammal, e.g., cancer, according to embodiments of the invention.

Provided herein are methods of perfusion culturing an adherent mammalian cell using a shake flask and a plurality of microcarriers, and various methods that utilize these culturing methods.