A method of enhancing the binding of growth factors and cell cultures to a demineralized allograft bone material which includes applying ex vivo an effective quantity of an ionic force change agent to at least a portion of the surface of a demineralized allograft bone material to produce a binding-sensitized demineralized allograft bone material and implanting the binding-sensitized demineralized allograft bone material into a host bone. The ionic force change agent may include at least one of enzymes, pressure, chemicals, heat, sheer force, oxygen plasma, supercritical nitrogen, supercritical carbon, supercritical water or a combination thereof. A molecule, a cell culture, or a combination thereof is administered to the binding-sensitized demineralized allograft bone material.

The invention relates to methods of preparing a bone matrix solution, a bone matrix implant, and variants thereof. The invention also relates to methods of cell culture using the same. The invention further relates to bone matrix scaffolds comprising one or more bone matrix nanofibers, methods of preparing, and methods of use thereof. The invention also relates to methods of culturing cells and promoting differentiation of stem cells using the same.

Methods, systems and activated human mesenchymal stromal cells (hMSCs) from bone marrow regions distal from bone fractures, the hMSCs enhanced for encouraging healing of bone fractures. Systems and methods of activation for enhancing bone fracture healing hMSCs, and the enhanced cells themselves, by exposing and activating distally obtained bone marrow aspirate to acoustic energy prior to placement of the activated cells at a site of a bone fracture.

The invention provides natural multi-composite bone implants such as bone-connective tissue-bone and osteochondral implants for the replacement and/or repair of, for example and in particular a damaged or defective bone-meniscus-bone joint or a bone-patella tendon-bone joint or osteochondral lesions, methods of preparing the composites and uses thereof. The invention also provides natural or native composite bone-connective tissue-bone and osteochondral matrices or scaffolds that are substantially decellularised for subsequent transplantation/implantation.

A method for making a porous devitalised scaffold suitable for use in repair of osseous, chondral, or osteochondral defects in a mammal comprises the steps of providing micronized extracellular matrix (ECM) tissue, mixing the micronized extracellular matrix with a liquid to provide a slurry, and freeze-drying the slurry to provide the porous scaffold. A porous scaffold suitable for use in repair of osseous, chondral, or osteochondral defects in a mammal and comprising a porous freeze-dried matrix formed from micronised decellularised extracellular matrix tissue is also described.

The disclosure provides bone graft materials, methods for their use and manufacture. Exemplary bone graft materials comprise combining a radiopaque component with a cancellous bone component to produce a bone graft material, wherein the cancellous bone component comprises native osteoreparative cells. Methods for treating a subject with the bone graft material are also provided.

Provided is a magnetically actuated microscaffold for minimal invasive osteochondral regeneration. More particularly, provided is a composition for cartilage regeneration, a microscaffold for cartilage regeneration, in which magnetic particles and cartilage regeneration cells are loaded on the surface of or within a 3-dimensional porous microstructure composed of a biodegradable polymer and having a diameter of 200-300 μm; and a microscaffold for bone regeneration, in which magnetic particles and bone regeneration cells are loaded on the surface of or within a 3-dimensional porous microstructure composed of a biodegradable polymer and having a diameter of 700-900 μm.

The present disclosure is directed at a process to form bone grafting material. One may provide a porous collagen scaffold and insert the scaffold into a perfusion chamber of a perfusion flow system. This may then be followed by continuously providing a mineralization perfusion fluid flow through the scaffold at a flow rate to provide dynamic intrafibrillar mineralization of the scaffold and form a collagen/hydroxyapatite composite scaffold. One may optionally provide the scaffold with bone tissue forming cells and then deliver a perfusion fluid including oxygen and one or more nutrients through the collagen/hydroxyapatite composite scaffold and to the bone tissue forming cells at a flow rate such that the bone tissue forming cells remodel the collagen/hydroxyapatite composite scaffold and form a bone tissue extracellular matrix. The bone tissue extracellular matrix may then be decellularized to form an acellular bone repair scaffold.

The present invention provides scaffolds that include a polymer and a cyclic peptide ligand. The peptide ligand increases the attachment of endothelial cells and/or progenitor cells to the scaffold. The present invention also provides engineered tissues that include the provided scaffolds. The present invention also provides coatings that include a coating polymer and a cyclic peptide ligand. The present invention also provides methods of improving endothelialization and vascularization of endothelial cells and/or progenitor cells for tissue regeneration in a subject and of repairing bone defects in a subject, by implanting a provided scaffold.

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.