Star block copolymers having 3 to 8 arms are formed as a 3D foam scaffold having tailor-made pore sizes that mimic an actual cell size of a specific animal and/or human tissue and/or organs. The pore sizes are made within the elastomeric foams via a salt leaching process wherein a salt of a specific particle size is blended within the star block copolymers and crosslinked as by polyisocyanate compounds. Water or other suitable solvent are utilized to dissolve and leach out the salt leaving an open pore system. Animal and/or human cells are then injected into the 3D elastomeric foam scaffold that contains pendant liquid crystals on the star block copolymer whereby with the aid of nutrients, cells are formed within the pore system that are viable for at least three months. The size of the pore is predetermined to produce a desired cultured cell having a desired size. The tissue and/or cells within the elastomeric scaffold can be applied to animal and/or human tissue and/or organs whereupon they grow and reconstruct the damaged, injured, diseased, etc., area and result in a healthy, repaired, and viable tissue or organ. The elastomeric liquid crystal containing foam scaffold will degrade naturally and/or also be consumed by the growing cells so that it no longer exists. In other words, a specific type of animal or human cell can be culturally produced having a predetermined average cell diameter that is substantially or essentially the same diameter of a natural cell.

A biomaterial for the treatment of spinal cord or of peripheral nerve injury, obtainable by: a) treating a hyaluronic acid derivative with a coating solution promoting Neuronal Stem Cells adhesion, branching and differentiation; b) contacting isolated Neuronal Stem Cells with the hyaluronic acid derivative obtained from step a) and culturing and expanding the absorbed cells in the presence of growth or neurotrophic factors selected from FGF (basic fibroblast growth factor), CNTF (ciliary neurotrophic factor), BDNF (brain derived neurotrophic factor) and GDNF (glial derived neurotrophic factor) or mixtures thereof.

The present invention addresses the problem of providing a method for obtaining Schwann cells directly (by direct reprogramming) without passing through pluripotent stem cells, such as ES cells or iPS cells. As a means for solving this problem, the present invention provides a method for preparing Schwann cells that includes a step of introducing into somatic cells of a mammal at least one gene selected from the group consisting of SOX10 genes and KROX20 genes, or an expression product thereof.

A method of producing an acellular cornea includes steps of subjecting a cornea of an animal to a decellularization process, and has not the step of treating the cornea with a protease, a chelating agent, a detergent, a glycerol, or a combination thereof. When a native cornea is processed by the method, the native structure and conformation of the native cornea are preserved while immunogenic matters are reduced to a level that the thus produced cornea may serve as a three-dimensional scaffold for host cells to grow thereon after transplantation.

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.

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.

A method is disclosed for coating and patterning hydrogels in order to modify surface properties. The method exploits the water content of the hydrogel and the hydrophobicity of the reaction solvent to create a thin oxide adhesion layer on the hydrogel surface. This oxide adhesion layer enables rapid transformation of the hydrophilic, cell non-adhesive hydrogel into either a highly hydrophobic or a cell-adhesive hydrogel by reaction with an alkylphosphonic acid or an ,-diphosphonoalkane, respectively. Also disclosed are coated, patterned hydrogels and constructs comprising the coated, patterned hydrogels.

A method is provided for forming an electrically conductive pathway between the nervous system of a patient and a prosthetic device. The method includes implanting an electrically conductive scaffolding around a nerve in the body of the patient; attaching the scaffolding to an electrical conduit which electrically transmits the action potential of the nerve; inducing growth of the nerve about the scaffolding and the electrical conduit, thereby forming an electrically conductive pathway; and bringing the electrically conductive pathway into electrical communication with the prosthetic device.

Disclosed herein are methods involving the targeting of 5HT biosynthesis in gut insulin-negative cells to convert them into insulin-positive cells. Also, disclosed are methods for treating a disease or disorder in a mammal, preferably a human, associated with impaired pancreatic endocrine function, by administering a therapeutically effective amount of an enumerated active agent that reduces the expression, biosynthesis, signaling or biological activity of serotonin or increases its degradation, wherein administering comprises delivering the agent to Gut Ins cells in the mammal. Other embodiments of the method are directed to therapy wherein an agent that significantly reduces FOXO1 expression, biosynthesis, signaling or biological activity or increases its degradation is administered in addition to the agent that reduces serotonin, or alternatively an agent that reduces FOXO1 expression is targeted to serotonin-positive gut enteroendocrine cells.

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.