[Object] Provided is a method of producing a nerve fascicle including efficiently extending axons of neural cells.

[Solution] Neural cells are cultivated in the presence of feeder cells including at least one type of cells selected from the group consisting of vascular component cells, perivascular cells, and oligodendrocytes.

The present invention provides, among other things, methods for producing platelets including the steps of providing a silk membrane about 2 μm and 100 μm thick, inclusive, contacting the silk membrane with a porogen to form a porous silk membrane comprising at least one silk wall defining a lumen, associating the porous silk membrane with stromal derived factor-1? and at least one functionalizing agent, forming a three dimensional silk matrix comprising interconnected pores wherein the pores have a diameter of between about 5 and 500 μm, inclusive, wherein the silk matrix is formed around at least a portion of the porous silk membrane, introducing a plurality of megakaryocytes to the silk matrix such that the megakaryocytes are located at least partially within the porous silk matrix, and stimulating the plurality of megakaryocytes to produce platelets. Also provided are various new compositions and methods of making those compositions.

An in vitro population of human brain endothelial cells (hBECs) expressing claudin-5, occludin, ZO-1 and GLUT-1 and expressing one or more of FZD7, WNT7A, WNT7B, APCDD1, STRA6 and ZO-3 is provided. A blood brain barrier (BBB) comprising the hBECs and use of the BBB for analyzing permeability characteristics of a test agent are provided.

Methods for mimicking a tumor microenvironment in vitro are provided. The methods comprise indirectly applying a shear stress upon at least one tumor cell type plated on a surface within a cell culture container. Methods for mimicking tumor metastasis and methods for testing drugs or compounds in such systems are also provided.

The invention relates to a cell sheet construct for neurovascular reconstruction. The cell sheet construct has a vascular endothelial cell layer and a neural stem cell layer, and the two layers are physically in direct contact with each other, where the vascular endothelial cell layer forms branching vasculatures, and the neural stem cell layer differentiates into neurons. The invention also relates to a method for manufacturing the cell sheet construct, having the following steps: culturing vascular endothelial cells on a substrate to form a vascular endothelial cell layer, seeding neural stem cells on the vascular endothelial cell layer to make the neural stem cells be physically in direct contact with the vascular endothelial cell layer, and culturing the neural stem cells and the vascular endothelial cell layer to differentiate into neurons and branching vasculatures to form a cell sheet construct.

Disclosed is a method for producing an in vitro model for blood-brain barrier, including (a) a culturing conditionally immortalized astrocytes on one surface of a porous membrane and culturing conditionally immortalized brain pericytes on the other surface of the porous membrane, until both of the cells become a sheet; (b) culturing conditionally immortalized brain microvascular endothelial cells in a culture vessel, until the cells become a sheet; (c) peeling off the sheet of conditionally immortalized brain microvascular endothelial cells; (d) allowing the sheet of conditionally immortalized brain microvascular endothelial cells to come into contact with the sheet of conditionally immortalized brain pericytes, so that the sheets are arranged in layers; and (e) co-culturing a cell culture comprising three layers consisting of the sheet of conditionally immortalized brain microvascular endothelial cells, the sheet of conditionally immortalized brain pericytes, and the sheet of conditionally immortalized astrocytes.

The present invention is in the field of the cultivation of biological cells and tissues with organ-like function on a microphysiological scale and provides a method for the microphysiological co-cultivation of 3D organoid tissue and at least one 2D cell layer.

The invention relates to a method for generating a cardiac tissue mimetic, comprising the steps of mixing cardiomyocytes (CM) and fibroblasts (FB) at a ratio from 2.5:1 to 10:1, thereby providing a first mixture, incubating said first mixture, such that said cardiomyocytes and said fibroblasts form a spherical structure, adding endothelial cells (EC) to said spherical structure at a ratio of cardiomyocytes (CM) to endothelial cells (EC) from 1.5:1 to 4:1, thereby providing a second mixture, and incubating said second mixture, such that a cardiac tissue mimetic is formed.

The invention further relates to a cardiac tissue mimetic comprising cardiomyocytes (CM), endothelial cells (EC), and fibroblasts (FB), wherein said cardiac tissue mimetic comprises sarcomeric structures and vascular structures.

Further aspects of the invention are the cardiac tissue mimetic for use in a method for heart tissue repair or replacement and a method for screening a compound using a cardiac tissue mimetic.

The present disclosure relates to a liver organoid, more specifically, to a liver organoid in which a liver lobule-type structure can be maintained for a long time and a preparation method using the same. The liver organoid of the present disclosure comprises: a tubular outer cavity the inside of which is divided into a plurality of compartments; a cell aggregate loaded into the compartments; and an inner cavity located at the core of the outer cavity.

The present disclosure relates to methods for expanding populations of hematopoietic stem cells (HSCs) using a genetically engineered human fetal liver niche and compositions of purified ex vivo expanded HSCs. Also provided herein are methods of using such expanded HSC cell populations for clinical applications including allogeneic hematopoietic stem cell transplantation and for drug discovery and modeling human liver development.