An object of the present invention is to provide an adhesion preventing material capable of preventing adhesion safely and efficiently. The present invention provides an adhesion preventing material comprised of a cell sheet containing mesothelial cells; an adhesion preventing method and organ regeneration promoting method each using the cell sheet containing mesothelial cells.

Disclosed are an artificial biomembrane using a silk matrix and a method of manufacturing the same, wherein the artificial biomembrane is configured such that a silk matrix having a cross-section with a first thickness, produced from silkworms, is subjected to planar division into two or more silk matrix pieces having a predetermined shape with the first thickness. Furthermore, the manufacturing process is relatively simple, thus reducing the manufacturing cost compared to when manufacturing typical artificial biomembranes, and moreover, the artificial biomembrane can exhibit outstanding cell culture capacity, is biocompatible, and has superior tensile strength and elongation, which are required of biomembranes.

Disclosed are an artificial biomembrane using a silk matrix and a method of manufacturing the same, wherein the artificial biomembrane is configured such that a silk matrix having a cross-section with a first thickness, produced from silkworms, is subjected to planar division into two or more silk matrix pieces having a predetermined shape with the first thickness. Furthermore, the manufacturing process is relatively simple, thus reducing the manufacturing cost compared to when manufacturing typical artificial biomembranes, and moreover, the artificial biomembrane can exhibit outstanding cell culture capacity, is biocompatible, and has superior tensile strength and elongation, which are required of biomembranes.

A method of treating a spinal cord injury in a subject in need thereof is disclosed. The method comprises implanting a scaffold into the spinal cord of a subject, wherein the scaffold is seeded with oral mucosa stem cells (OMSC) and/or cells that have been ex vivo differentiated from said OMSCs, thereby treating the spinal cord injury.

Described herein are hydrogels attached to a base with the strength and fatigue comparable to that of cartilage on bone and methods of forming them. The methods and apparatuses described herein may achieve an attachment strength between a hydrogel and a substrate equivalent to the osteochondral junction. In some examples the hydrogel may be a triple-network hydrogel (such as BC-PVA-PAMPS) that is attached to a porous substrate (e.g., a titanium base) with the shear strength and fatigue strength equivalent to that of the osteochondral junction.

An alloprosthetic composite implant comprising includes a structural porous scaffold having a pore density profile corresponding to a density profile of bone to be replaced. A plurality of cells are seeded within pores of the porous scaffold and grown by incubation. The cells may include osteoblasts and/or stem cells to form the structure of the implant, and one or more cartilage layers may be grown on top of the scaffold. The pore density profile of the scaffold may be formed based on one or both of the bone density profile of the bone to be removed, and the bone density profile of the native bone that will be in contact with the alloprosthetic implant. A robot may be employed reo resect the native bone and also to shape the alloprosthetic implant to fit into place in the native bone.

The present disclosure provides tissue products produced from extracellular tissue matrices. The tissue products can include acellular extracellular matrices including combinations of different tissue types. The combination can harness various properties of the different tissues to provide improved composite structures with desired mechanical and/or biologic properties.

A composite material can include a gel and at least one nanostructure disposed within the gel. A method for healing a soft tissue defect can include applying a composite material to a soft tissue defect, wherein the composite material includes a gel and a nanostructure disposed within the gel. A method for manufacturing a composite material for use in healing soft tissue defects can include providing a gel and disposing nanofibers within the gel.

Methods of treating a complex wound by administering to a complex wound in the individual a therapeutically effective amount of a fetal support tissue product to treat the complex wound. Methods of treating a complex lower extremity ulcer by administering to a complex lower extremity ulcer in the individual a therapeutically effective amount of a fetal support tissue product to treat the complex lower extremity ulcer. Methods of reducing or preventing scar formation from granulation tissue by administering a fetal support tissue product to granulation tissue. Methods of repairing a spina bifida defect by administering to the defect in the individual a therapeutically effective amount of an umbilical cord product.

A bioprosthetic valve for repairing a deep venous insufficiency in a subject includes a single leaflet from a xenogeneic heart valve attached at natural margins of attachment to a patch of valve wall tissue. The patch may extend axially above and below the leaflet and circumferentially on either side of the leaflet to provide a region for attaching the patch to a fenestration in a host vein. A bioprosthetic valve may be manufactured by excising a portion of a xenogeneic heart valve including a single leaflet and contiguous wall tissue, and may further comprise shaving off excess leaflet tissue from adjacent leaflets. A method of replacing a malfunctioning venous valve in a subject includes providing a bioprosthetic valve as described above and inserting it to the host vein.