A method of screening for a substance that acts on a cell mass includes producing a cell mass by three-dimensional culture of primary cancer cells using a tumor tissue, adding a test substance to the cell mass, and evaluating an action of the test substance on the cell mass. The cell mass is produced by culturing cells obtained from the tumor tissue in a medium containing a 5% v/v or less extracellular matrix on a substantially low-adhesive cell culture substrate and producing the cell mass of the primary cancer cells.

Provided herein is a method for preparing microcarrier particles, comprising the steps of allowing the dispersed phase liquid flow through a multi-hole plate at a low temperature to form liquid microspheres in a continuous phase, and enabling a synthetic polymer and/or natural biological macromolecules within the liquid microspheres to be subject to a curing reaction at a low temperature to form particles. Further provided herein are the method for preparing an emulsion and an apparatus and process system for preparing microcarrier particles, which can be used for preparing emulsions and microcarrier particles on a large scale.

A method for producing a professional antigen-presenting cell, including inducing expression of c-MYC, BMI1, and MDM2 in a myeloid cell (MC) to obtain a proliferative myeloid cell (pMC), and inducing expression of GM-CSF and/or M-CSF in the pMC to obtain a professional antigen-presenting cell (pAPC). The myeloid cell is a myeloid cell differentiated from a pluripotent stem cell.

The present invention provides a method for efficiently separating and purifying functional pituitary hormone-producing cells and/or progenitor cells thereof from differentiated tissues derived from pluripotent stem cells.

Culture media capable of promoting differentiation of pluripotent stem cells (PSCs) into mesenchymal stem cells (MSCs) or supporting expansion of MSCs is provided. Methods of differentiation of PSCs into MSCs are provided. Methods of expanding MSCs without differentiation are also provided.

The application provides biocompatible carriers comprising bone forming and/or cartilage forming cells and methods for making them. The application further provides pharmaceutical compositions comprising said ATMPs and method of treatments using said ATMPs. The application further relates to said ATMPS for use in the treatment of bone disorders, cartilage disorders and joint disorders. The current invention further relates to method of treatments of bone disorders, cartilage disorders and joint disorders.

A hydrogel capsule comprising a stem cell core that has been induced to differentiate into a hematopoietic lineage cell, and methods for the production of hematopoietic lineage cells from stem cells encapsulated in a hydrogel.

A modular engineered tissue construct includes a plurality of fused self-assembled, scaffold-free, high-density cell aggregates. At least one cell aggregate includes a plurality of cells and a plurality of biocompatible and biodegradable nanoparticles and/or microparticles that are incorporated within the cell aggregates. The nanoparticles and/or microparticles acting as a bulking agent within the cell aggregate to increase the cell aggregate size and/or thickness and improve the mechanical properties of the cell aggregate as well as to deliver bioactive agents.

Provided is a method for producing a three-dimensional tissue having a vascular system structure, said method comprising: (a) a step for forming a vascular system structure template using a gel; (b) a step for forming a three-dimensional tissue in the vicinity of the template; (c) a step for dissolving the template using a cationic solution; and (d) a step for seeding vascular endothelial cells and/or lymphatic vessel endothelial cells in a void remaining after the dissolution of the template. Also provided is a method for producing a three-dimensional tissue having a vascular system structure, said method comprising: (i) a step for forming a vascular system structure template using a gel; (ii) a step for seeding vascular endothelial cells and/or lymphatic vessel endothelial cells on the template; (iii) a step for forming a three-dimensional tissue in the vicinity of the cells seeded above; and (iv) a step for dissolving the template using a cationic solution. Also provided is a three-dimensional tissue comprising a gel which has a vascular system structure.

Provided herein are constructs of micro-aggregate multicellular, minimally polarized grafts containing Leucine-rich repeat-containing G-protein coupled Receptor (LGR) expressing cells for wound therapy applications, tissue engineering, cell therapy applications, regenerative medicine applications, medical/therapeutic applications, tissue healing applications, immune therapy applications, and tissue transplant therapy applications which preferably are associated with a delivery vector/substrate/support/scaffold for direct application.