The present disclosure provides fasciculated nerve grafts of customizable lengths and diameters, and methods of preparing the same. The grafts are made by digesting native extracellular matrix (ECM) around the nerve fascicles of a nerve tissue, and the epineurial sheath. One or more of the individual fascicles may then be entubulated in an entubulation material, embedded in or coated with a coating material, or both, to form a fasciculated nerve graft. The fasciculated nerve grafts are customizable and designed to bridge nerve gaps; the modularity of the fasciculated nerve graft allows for restoring continuity to nerve defects of virtually any length and allows for matching the diameter of the patient's recipient nerve.

Described herein are biomaterials, systems, and methods for guiding regeneration of an epiphyseal growth plate or similar interfacial tissue structures. In one aspect, the disclosed technology can include a biologic material that can comprise one or more of a hydrogel carrier for growth factors and MSCs, chondrogenic and immunomodulatory cytokines, microparticles for prolonged and spatially controlled growth factor delivery; and/or porous scaffold providing mechanical support. The implanted material can be applied via various different modalities depending on the nature of the physeal injury. One modality is an injectable hydrogel and another modality is an implantable hydrogel infused scaffold.

An object of the present invention is to provide a method for producing a gelatin formed body having a minimized content of a component harmful to a living body and high biocompatibility with high shaping accuracy, and a gelatin formed body produced by the method. According to the present invention, provided is a method for producing a gelatin formed body, the method including: a step a of forming, on a substrate, a layer containing a powder which is obtained by air-drying an aqueous gelatin solution and has an average particle diameter of 25 to 200 μm; and a step b of jetting liquid droplets of an aqueous solution containing alcohols having a boiling point of 120° C. or lower toward the layer formed in the step a from a nozzle and flying the jetted liquid droplets so that the liquid droplets are landed on the layer formed in the step a, thereby forming a gelatin formed body.

A 3D bioprintable ink formulation capable of multidimensional printing comprises gelatin modified by an essential amino acid arginine, oxidized alginate and a catalyst.

A preparation method of calcium peroxide-mediated in situ crosslinkable hydrogel as a sustained oxygen-generating matrix, includes: a) reacting a natural or a synthetic polymer with Traut's reagent (TR) in a solvent, and synthesizing a polymer derivative having thiol group in backbone of the polymer derivative; and b) mixing and reacting a solution of the polymer derivative having thiol group with calcium peroxide (CaO.sub.2), and thereby forming a hydrogel, wherein in the step b), disulfide bonds (—S—S) are induced between backbones of the polymer derivative having thiol group attached by decomposition of calcium peroxide (CaO.sub.2), and thereby in situ crosslinking is formed.

A valved conduit including a bioprosthetic valve, such as a heart valve, and a tubular conduit sealed with a bioresorbable material. The bioprosthetic heart valve includes prosthetic tissue that has been treated such that the tissue may be stored dry for extended periods without degradation of functionality of the valve. The bioprosthetic heart valve may have separate bovine pericardial leaflets or a whole porcine valve. The sealed conduit includes a tubular matrix impregnated with a bioresorbable medium such as gelatin or collagen. The valved conduit is stored dry in packaging in which a desiccant pouch is supplied having a capacity for absorbing moisture within the packaging limited to avoid drying the bioprosthetic tissue out beyond a point where its ability to function in the bioprosthetic heart valve is compromised. The heart valve may be sewn within the sealed conduit or coupled thereto with a snap-fit connection.

A bio-ink composition comprises a plurality of bio-block, in which the bio-blocks can serve as basic building blocks in cell-based bioprinting. The bio-blocks, pharmaceutical compositions comprising the bio-blocks, methods of preparing artificial tissues, tissue progenitors, or multi-dimensional constructs, and methods of preparing the bio-blocks are also provided. The bio-blocks, and the multi-dimensional constructs, artificial tissues, and tissue progenitors comprising the bio-blocks or prepared by the methods described herein are useful for tissue engineering, in vitro research, stem cell differentiation, in vivo research, drug screening, drug discovery, tissue regeneration, and regenerative medicine.

The present invention relates to a material for bone implants, comprising: a surface of oxidic ceramic materials, titanium or polyether ether ketone (PEEK) or other polymer or composite materials, a matrix of collagen or gelatin, which is covalently bound to said surface, and calcium phosphate embedded into said matrix. The present invention further relates to a method for producing the material according to the invention, to bone implants comprising the material according to the invention, and to its use as a bone implant material.

The present invention provides compositions and methods for repair and reconstruction of defects and injuries to the cornea.

Scaffolding constructs, medical devices comprising scaffolding constructs, and related methods of manufacturing and treatment are described. The scaffolding construct may comprise a biocompatible material, such as a polymer, copolymer, or hydrogel. The scaffolding construct may be porous and at least partially bioresorbable. Further, for example, the scaffolding construct may define a cavity for securing a medical implant therein.