A method of immobilizing extracellular vesicles in an extracellular matrix material provides for improved extracellular vesicle retention in vitro and in vivo. Extracellular matrix materials, such as collagen, are functionalized with chemicals that are complimentary to ligands disposed on the surface of the extracellular vesicle. In one example embodiment, collagen is functionalized with dibenzocyclooctyne and the extracellular vesicle is functionalized with an azide tag. The extracellular vesicle is immobilized within the collagen through a click reaction involving the dibenzocyclooctyne and the azide tag.

Disclosed are various bioactive grafts and methods of making the same. In one embodiment, bone material is harvested from a donor. The harvested bone material is exposed to a lysing agent, the lysing agent configured to release growth factors and bioactive materials from cellular material of the harvested bone material. The harvested bone material is then rinsed with a rinsing agent. The pH of the harvested bone material is substantially neutralized.

The present disclosure relates to tissue engineering, and more particularly to a method for treating or repairing rotator cuff or other tendon tears or damage using scaffold-free, 3-dimensional engineered tendon constructs.

Medical material and a method for preparing a biological tissue for a medical application are provided. The material is useful as a sealing element in a heart valve prosthesis. A method includes decellularizing the biological tissue by decellularizing solution to obtain an acellular extracellular matrix, solubilizing the extracellular matrix of the biological tissue, and crosslinking collagen fibers of the solubilized extracellular matrix.

Grafts modified with one or more bioactive substances are provided, as well as methods to make and use them. More particularly, the present invention relates to modified grafts having characteristics which facilitate tissue generation, repair, and reconstruction, and which are modified with bioactive substances, such as one or more proteins and minerals, whose bioactivity further facilitates tissue generation, repair, and reconstruction. Methods for producing the modified grafts include depositing the one or more bioactive substances onto, into, or both, a substrate material. In certain exemplary embodiments, the substrate material comprises a tissue derived matrix produced by processing one or more tissue samples, and the bioactive materials are precipitated from a solution produced during that processing, such as during demineralization of bone tissue samples or delipidation of adipose tissue samples, wherein the one or more bioactive substances comprise proteins and minerals endogenous to bone or adipose tissue, respectively.

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.

Provided are methods for preparing gelled, solubilized extracellular matrix (ECM) compositions useful as cell growth scaffolds. Also provided are compositions prepared according to the methods as well as uses for the compositions. In one embodiment a device, such as a prosthesis, is provided which comprises an inorganic matrix into which the gelled, solubilized ECM is dispersed to facilitate in-growth of cells into the ECM and thus adaptation and/or attachment of the device to a patient.

The invention is directed to a biological bandage derived from fish skin (e.g. tilapia skin) that can be used with healing of wounds such as burn wounds. The edible property of the fish skin biological bandage according to various embodiments makes it suitable for both human and veterinary medicine.

The present disclosure relates to methods of preparing personalized blood vessels, useful for transplantation with improved host compatibility and reduced susceptibility to thrombosis. Also provided are personalized blood vessels produced by the methods and use thereof in surgery.

Provided are an anticoagulation and anticalcification biological material and a preparation method therefor. The preparation method includes the following steps: introducing, on a biological tissue, a polymerizable reactive group, and undergoing free radical copolymerization with a zwitterion. In the present disclosure, by introducing a reactive group capable of free radical polymerization to a biological tissue and undergoing free radical copolymerization with a zwitterionic monomer, collagen in the biological tissue is crosslinked at multiple sites by means of a polymer, thereby achieving sufficient crosslinking within and between collagen fibers, improving the stability of the biological tissue, and prolonging the service life of the biological tissue. Moreover, a zwitterion is introduced to the surface of the biological tissue, to improve the anticoagulation performance, promote the in-situ endothelialization of a biological valve, and prevent the calcium element deposition.