The present invention provides a limb bud mesenchymal cell population, which is derived from mammalian lateral plate mesoderm cells, and is PRRX1 protein-positive.

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.

Disclosed is a method of producing reconstructed human skin including forming a three-dimensional hydrogel scaffold matrix by gelling a matrix solution including a type I collagen solution, forming a coating layer by coating the three-dimensional hydrogel scaffold matrix with type IV collagen, and forming an epidermis by seeding epidermal keratinocytes onto the three-dimensional hydrogel scaffold matrix having the coating layer formed thereon and performing culture.

It is provided a method of producing high-quality engineered cartilage graft in a human of animal, such as nasal cartilage graft, comprising expanding chondrocytes and/or chondroprogenitors, e.g. autologous human nasoseptal chondrocytes (hNC,) from a donor patient by selecting expanded chondrocytes and/or chondroprogenitors by detecting the expression of at least one surfaceome protein gene or secretome protein gene, wherein the at least one surfaceome protein gene is ADGRG1, NPR3, SLC16A4, TSPAN13, FZD4 and SLC22A23 and the at least one secretome protein gene is ADGRG1, B3GNT7, COLGALT2, IGFBP3, STC2, SAA1, ANGPLT1, COL8A2, INHBB, ADAMTS9, ORM1, COL14A1, DCN, COL21A1, ENOX1, IL7, MXRA5 GAL, TFRC, SERPINA9, LIF, GDF6 and COL5A3.

The present invention relates to a method for fabrication of an extracellular matrix-induced self-assembly and to fabrication of an artificial tissue using same. The method for fabrication of an extracellular matrix-induced self-assembly comprise the steps of: (a) decellularizing and powdering a tissue-derived extracellular matrix (ECM); and (b) adding the decellularized extracellular matrix powder to cells and culturing the cells to form a cell-extracellular matrix powder self-assembly. Accordingly, the self-assembly has characteristics similar to those of extracellular matrix tissues and can be fabricated into three-dimensional artificial tissues 1 cm or greater in size, thus finding advantageous applications as a cell therapy product and an artificial tissue implant.

The disclosure provides a biological brain-computer interface comprising genetically modified cells engrafted onto an adult mammal (e.g., mouse) above cortical layer 1, forming an artificial cortical layer termed layer zero (L0). Following engraftment, L0 goes through a developmental process characterized by synchronous waves of activity that gradually recede to resemble spontaneous cortical activity. Axons and dendrites from L0 nondestructively infiltrated the host cortex and formed synaptic connections necessary for bidirectional communication with the brain.

The present invention is directed to tissue substitute materials and uses thereof useful for the treatment of wound, skin wounds and in particular chronic ulcers. The invention further relates to methods of preparation of those tissue substitute materials.

A material for inducing nerve regeneration in a transplantation site, or a material for recovering the function of nerve tissues in a transplantation site, the material comprising a cell structure having a thickness of at least 300 μm that is constructed by stacking the spheroids of bone marrow-derived cells, adipose tissue-derived cells, dental pulp-derived cells, amnion-derived cells, placenta-derived cells, umbilical cord-derived cells, or umbilical cord blood-derived cells, on a needle-shaped body arranged on a substrate.

Compositions and methods for the prevention and/or treatment of conditions involving disease or damage in mammalian cartilage and bone, using mesenchymal stem cells isolated with anti-integrin α10 antibodies are disclosed.

The present invention provides a method for producing a retinal progenitor cell, including (1) a first step of subjecting pluripotent stem cells to floating culture in a serum-free medium to form an aggregate of pluripotent stem cells, and (2) a second step of subjecting the aggregate formed in step (1) to floating culture in a serum-free medium or serum-containing medium each being free of a substance acting on the Sonic hedgehog signal transduction pathway but containing a substance acting on the BMP signal transduction pathway, thereby obtaining an aggregate containing retinal progenitor cells.