A method for arterial endothelial-enhanced functional T cell generation is provided. In the method, arterial endothelial cells enhance functional T cell generation by promoting the generation of hematopoietic progenitor cells with T-lineage bias. The first stage of T cell differentiation from human pluripotent stem cells (hPSCs) is optimized, and it is found that hPSC-derived autologous arterial endothelial cells increase the T cell potential of hematopoietic progenitor cells. Moreover, the T cells generated by arterial endothelial cell priming share similar function to that of human peripheral blood T cells. hPSC-derived CD19-CAR-T cells have been verified to have tumor-killing effects both in vivo and in vitro. The established hPSC-T differentiation system would provide a valuable resource for chimeric antigen receptor T cell (CAR-T) therapy.

Disclosed herein is a device comprising a microelectrode comprising cells cultured on a surface of the microelectrode and a porous membrane comprising an upper surface comprising cultured cells. Further, devices and methods for in in-vitro models of the blood-brain barrier (BBB) and for modeling the transport across this barrier are disclosed.

The systems and methods of the present disclosure can be used to generate systems and models that are physiologically relevant to the human and animal system. These physiological conditions can be designed to mimic the actual human condition for cell differentiation and proliferation. The system and methods of this present disclosure allow the formation of an appropriate biomaterial to mimic that which exists in a human or animal scaffold. Utilizing 3D printing technology, a hydrogel scaffold can be printed at various resolution very close to human physiological geometry. Additionally, the architecture can be optimized for the selected application and appropriate cells can be seeded on the scaffold prior to testing.

The present invention provides a product comprising plated human hepatocytes on a surface and at least some of the plated hepatocytes are in one or more hepatocyte clusters on feeder cells, which are attached to the surface. A method of preparing plated human hepatocytes is also provided. The preparation method comprises applying human hepatocytes to a surface in the presence of feeder cells, co-culturing the applied hepatocytes with the feeder cells, and forming one or more hepatocyte clusters by the co-cultured hepatocytes on the feeder cells, which are attached to the surface. The plated hepatocytes may be used for various purposes, including the preparation of a hepatitis B virus (HBV) infected hepatocyte culture model and drug testing.

Improved hybrid neurovascular spheroids and methods for making the same are provided. In some embodiments of a method for making a hybrid neurovascular spheroid, the method includes i) propagating cortical cells to form a cortical spheroid; ii) propagating endothelial cells to form an endothelial spheroid; iii) propagating mesenchymal stem cells to form a mesenchymal cell culture; and iv) combining the cortical spheroid, endothelial spheroid, and mesenchymal spheroid under conditions to form the hybrid neurovascular spheroid.

The invention relates to a method for the formation of renal tubules by embedding individual renal cells into a synthetic hydrogel, which is based on polyethylene glycol as a component, and the culturing of the cells until tubule structures are formed. The culturing can be continued until the obtained tubule structures correspond in terms of size, structure, morphology and functionality to adult human renal tubules or are at least similar thereto.

Provided are a method for producing a cell tissue, including a culturing step of culturing cells capable of serving as a feeder inside opening pores and communicating pores of a porous film having a plurality of the opening pores provided on a surface thereof and the communicating pores communicating mutually adjacent opening pores with one another; and a porous film including a plurality of opening pores provided on a surface thereof and communicating pores communicating mutually adjacent opening pores with one another.

Provided herein relates to devices for simulating a function of a tissue and methods of using the same. In some embodiments, the devices can be used to simulate a function of a human liver tissue. In some embodiments, the devices can be used to simulate a function of a dog liver tissue. Endothelial cell culture media for long-term culture of endothelial cells are also described herein.

The present description provides improved methods for generating thymic epithelial progenitor (TEP) cells from pluripotent stem (PS) cells in vitro. Also provided are isolated invitro cell populations, compositions, and systems comprising TEP cells produced in vitro. Compositions and systems of cell populations of thymic epithelial cells and subpopulations thereof, as well as cells formed during different stages of differentiation of PS cells into thymic epithelial cells and subpopulations thereof are provided.

A tissue construct is provided that comprises a pancreas derived microvessel fragment and a pancreatic islet cell. The pancreas derived microvessel fragment and the pancreatic islet cell can be incorporated into a biocompatible medium. Tissue constructs can be comprised of other cells, such as stem cells, combined with the pancreas derived microvascular fragment. Methods for isolating microvessel fragments from a pancreas are also provided and include enzymatic digestion of pancreatic tissue and separation of microvessel fragments from endocrine and exocrine tissue. Methods for treating diabetes are further provided and include administration of the tissue constructs.