A method for preparing a skin regeneration scaffold is disclosed. The method may include preparing a polymer solution by dissolving a biopolymer in a solvent, and subjecting the polymer solution to a template-assisted extrusion process with a nanoporous material as a template in order to produce polymer nanofibers. Furthermore, the method includes fabricating a multilayer composite nanofibrous scaffold using the polymer nanofibers. The composite nanofibrous scaffold may be seeded with cells. In some cases, the cells may be selected from autologous cells, allogeneic cells, or combinations thereof.

Described herein are methods of preparing human amniotic membrane tissue grafts derived from the placenta. The grafts are composed of three layers as seen in the amniotic membrane in utero. These grafts are processed using physiologic solutions, lyophilized and terminal sterilized (via gamma irradiation in a frozen state) that thereby preserves the graft in such a manner as to retain the naturally occurring biological properties of the amniotic membrane and offer a sterile graft for transplantation. By dehydration via lyophilization and terminal sterilization in a frozen state, the graft has the advantage of storage at ambient temperatures for prolonged periods of time prior to transplantation.

Described herein are methods of preparing human amniotic membrane tissue grafts derived from the placenta. The grafts are composed of three layers as seen in the amniotic membrane in utero. These grafts are processed using physiologic solutions, lyophilized and terminal sterilized (via gamma irradiation in a frozen state) that thereby preserves the graft in such a manner as to retain the naturally occurring biological properties of the amniotic membrane and offer a sterile graft for transplantation. By dehydration via lyophilization and terminal sterilization in a frozen state, the graft has the advantage of storage at ambient temperatures for prolonged periods of time prior to transplantation.

The present invention relates to a method for producing hair microfollicles comprising the steps of: a) providing de novo papillae, b) providing other cell populations selected from the group of fibroblasts, keratinocytes and melanocytes, and co-culturing the de novo papillae with at least one other cell population in non-adherent culture vessels. The present invention relates also to methods of producing de novo papillae usable in said method for producing hair microfollicles.

The present invention relates to a method for producing hair microfollicles comprising the steps of: a) providing de novo papillae, b) providing other cell populations selected from the group of fibroblasts, keratinocytes and melanocytes, and co-culturing the de novo papillae with at least one other cell population in non-adherent culture vessels. The present invention relates also to methods of producing de novo papillae usable in said method for producing hair microfollicles.

The present invention is directed to a method of producing a tissue graft, comprising at least steps of providing a gel, seeding the gel with cells of at least a first and/or cells of a second type, and culturing of the cells of the first and/or cells of the second type in said gel until the formation of at least one first biostructure in the gel by the cells of the first type and/or the cells of the second type.

The present invention is directed to a method of producing a tissue graft, comprising at least steps of providing a gel, seeding the gel with cells of at least a first and/or cells of a second type, and culturing of the cells of the first and/or cells of the second type in said gel until the formation of at least one first biostructure in the gel by the cells of the first type and/or the cells of the second type.

The present invention relates to a method for preparing a three-dimensionally cultured skin model comprising dermis and epidermis, which comprises: a step of preparing the dermis using a composition comprising murine fibroblasts; and native collagen or a combination of native collagen and atelocollagen; and a step of forming the epidermis using keratinocytes. Also, the present invention relates to a three-dimensionally cultured skin model which comprises: a dermis prepared by a composition comprising murine fibroblasts, native collagen, or a combination of native collagen and atelocollagen; and epidermis formed from keratinocytes. The three-dimensionally cultured skin model of the present invention may be used widely in toxicity and efficacy experiments of medicines or cosmetics, and in the field of alternative experiments for animal experiments since the three-dimensionally cultured skin model is excellent in formation and differentiation of dermis and epidermis using murine 3T3 cells for preparing the skin model and a mixture of atelocollagen and native collagen, and has a structure similar to the human skin layer by inhibiting dermal contraction and collagen degradation in the dermis.

A composite containing a fabric and a polyampholyte hydrogel is provided. In the composite, the polyampholyte hydrogel is a hydrogel of a polymer containing randomly dispersed cationic and anionic repeat groups and at least a part of the fabric is coated with the polyampholyte hydrogel. A method of preparation of the composite involves steps (a) to (c): (a) providing a monomer mixture for preparation of a polyampholyte hydrogel; (b) immersing a fabric in the monomer mixture solution; and (c) polymerizing monomers in the monomer mixture solution to obtain a precursor of the composite.

An electro-conductive hydrogel composite material that may be suitable as an artificial skin satisfies all four requirements of artificial skin, namely, flexibility, electrical conductivity, healing property, and biocompatibility. The electro-conductive hydrogel composite material includes a hydrogel composition including water and a cross-linkable polymer which reversibly forms cross-linkage by hydrogen bonding; and an electro-conductive material dispersed in the hydrogen bond-based hydrogel.