A method of making an electron beam irradiated osteoinductive implant is provided. The method comprises exposing an osteoinductive implant containing demineralized bone matrix (DBM) fibers to electron beam radiation at a dose of from about 10 kilograys to 100 kilograys for a period of time. The electron beam irradiation reduces microorganisms in the osteoinductive implant, and the electron beam irradiated osteoinductive implant retains osteoinductive properties. Methods of implantation and an irradiated osteoinductive implant are also disclosed.

Compositions and methods for augmenting bone formation by administering isolated human mesenchymal stem cells (hMSCs) within a matrix provided. By adding calcium and/or phosphate ions to the matrix, one may foster greater bone regeneration.

The present invention relates to a tissue substitute material for implantation, comprising (a) a substrate to be implanted covered with (b) a controlled release coating containing (c) at least one biologically substance that decreases bacterial growth, wherein the (b) controlled release coating is a bioavailable, biocompatible polymer material and wherein the (c) at least one biologically active substance that decreases bacterial growth. The present invention also relates to a method to prepare the tissue substitute material, as wells the uses thereof.

This invention provides solid substrates for mitigating or preventing cell or tissue adherence and/or vascularization, which solid substrates comprise a marine organism skeletal derivative and are characterized by a specific fluid uptake capacity value of less than 40%, processes for selection of the same and applications of the same. This invention also provides solid substrates for mitigating or preventing cell or tissue adherence and/or vascularization, which solid substrates are characterized by having a contact angle value of more than 60 degrees, when in contact with a fluid. This invention also provides solid substrates for mitigating or preventing cell or tissue adherence and/or vascularization, which solid substrate is characterized by a minimal surface roughness (Ra) or substantial surface smoothness, as measured by scanning electron microscopy or atomic force microscopy. The invention also provides processes for selection of an optimized coral-based solid substrate.

The present invention is directed to a fiber, preferably bone fiber, having a textured surface, which acts as an effective binding substrate for bone-forming cells and for the induction or promotion of new bone growth by bone-forming cells, which bind to the fiber. Methods of using the bone fibers to induce or promote new bone growth and bone material compositions comprising the bone fibers are also described. The invention further relates to a substrate cutter device and cutter, which are effective in producing substrate fibers, such as bone fibers.

An osteoinductive composition is provided which includes a plurality of surface demineralized fibrous bone chips. Each fibrous bone chip has a BET surface area from about 10 m.sup.2/gm to about 70 m.sup.2/gm. The osteoinductive composition can also include fully demineralized bone fibers. The osteoinductive composition including the surface demineralized fibrous bone chips with or without fully demineralized bone fibers can be placed in a covering, such as a mesh bag. The osteoinductive composition can include other bone structures and/or bioactive agents and/or ceramics. A method of treating a bone cavity in a patient in need thereof with the osteoinductive composition including a plurality of surface demineralized fibrous bone chips with or without fully demineralized bone fibers is also provided.

A biocompatible structure includes one or more base structures for regeneration of different tissues. Each base structure includes alternately stacked polymer layers and spacer layers. The polymer layer includes a polymer and tissue forming nanoparticles. The polymer includes polyurethane. The tissue forming nanoparticles includes hydroxypatites (HAP) nanoparticles, polymeric nanoparticles, or nanofibers. The spacer layer includes bone particles, polymeric nanoparticles, or nanofibers. The weight percentage of tissue forming nanoparticles to the polymer in the polymer layer in one base structure is different from that in the other base structures. A method of producing the biocompatible structure includes forming multiple base structures stacked together, coating the stacked multiple base structures, and plasma treating the coated structure.

Disclosed is a new use of a stem cell generator in preparation of bone defect repair materials, wherein the stem cell generator is formed by implanting a biomaterial with osteogenic induction capability or a biomaterial loaded with active substances and/or cells into an animal or a human body and generating organoids after development, the active substances are bone morphogenetic protein-2, or bone morphogenetic protein-7, other growth factors/polypeptides having bone regeneration induction ability, growth factors/polypeptide combinations, or a combination thereof. The cells are bone marrow-derived mesenchymal stem cells, adipose-derived mesenchymal stem cells or other derived mesenchymal stem cells; other types of cells with osteogenic differentiation capability; cells that aid in osteogenic differentiation of mesenchymal stem cells, such as vascular endothelial cells and the like. The stem cell generator is used to prepare bone repair materials for treatment of various types of bone defects or bone deformities that are spontaneous or caused by trauma.

This invention provides solid substrates for promoting cell or tissue growth or restored function, which solid substrate is characterized by a specific fluid uptake capacity value of at least 75%, which specific fluid uptake capacity value is determined by establishing a spontaneous fluid uptake value divided by a total fluid uptake value. This invention also provides solid substrates for promoting cell or tissue growth or restored function, which solid substrate is characterized by having a contact angle value of less than 60 degrees, when in contact with a fluid. This invention also provides solid substrates for promoting cell or tissue growth or restored function, which said substrate is characterized by a substantial surface roughness (Ra) as measured by scanning electron microscopy or atomic force microscopy. The invention also provides for processes for selection of an optimized coral-based solid substrate for promoting cell or tissue growth or restored function and applications of the same.

The present invention relates to the field of treatment of bone defects. The invention provides a composition for treatment of bone defects as well as methods for treatment of such defects.