A demineralized bone matrix (DBM) scaffold product comprising a plurality of elongate demineralised bone fibres mechanically interconnected with one another in a regular and repeating pattern.

Described herein are compositions comprising a BMP-2 derived peptide conjugated to albumin for use in bone grafts. The composition may further include bone matrix, such as demineralized bone matrix (DBM).

Provided herein is a 3D printing system and related compositions, and method of using such, that can produce a polymeric microfiber having embedded microspheres encapsulating an active agent with micron precision and high spatial and temporal resolution.

A method for producing xenogeneic bone graft, which is a material for use in bone tissue therapy, is provided. The method includes the steps of isolating the cancellous bones from cartilage and cortical bone by fragmenting them into pieces, washing the bone fragments with purified water to partially remove the organic phases and boiling them with purified water, contacting the bone fragments with a solvent for further removal/isolation of the organic phase, washing the bone fragments to remove the solvents used and other possible residues, subjecting them to a hydrothermal and/or solvothermal treatment with a solvent at a pressure of more than 1 atm and a temperature in the range of 100° C. to 300° C., after which washing them with purified water, and drying the cancellous bone fragments, for example, at a temperature in the range of 50° C. to 100° C. to dehydrate them.

A method for preparing a biological material for implanting provides irradiating at least a portion of the surface of the material with an accelerated Neutral Beam.

The present disclosure provides a bone-implantable device and methods of use. The bone-implantable device comprises a body having an exterior surface, wherein a portion of the exterior surface includes a cured osteostimulative material comprising MgO.

A method and system for making a bone plug using cortical bone material. A patient jaw having insufficient bone at a surgical site may be scanned to provide a 3D image which may be used to design a virtual bone plug and to fabricate the bone plug for placement within the patient. The bone plug may be formed from cortical bone that can be reconstituted and demineralized or demineralized and milled to shape.

The present disclosure provides a bone-implantable device and methods of use. The bone-implantable device comprises a body having an exterior surface, wherein a portion of the exterior surface includes a cured osteostimulative material comprising MgO.

Artificial meniscal scaffolds characterized by a composite of circumferential polymer fiber network and orthogonal polymer fiber network embedded in an arcuate bioresorbable matrix comprised of collagen and hyaluronic acid. The orthogonal polymer fiber network prevents separation of the circumferential polymer fiber networks. The polymer fiber networks convert axial compressive forces on the scaffolds to tensile loads on the circumferential polymer fibers. The composite scaffold can be anchored to bone by novel anchoring components that protect the polymer fibers and ensure immediate securement of the artificial meniscal scaffold to bone.

An intervertebral fusion device includes a structural ceramic body. The structural ceramic body has a bottom surface, a top surface, a peripheral surface connected between the bottom surface and the top surface, and at least one pore channel penetrating the bottom surface and the top surface. The inner surface of the pore channel is either a convex curved surface or a funnel-shaped surface. For the pore channel having the convex curved surface, the pore diameter of the pore channel gradually expands from the center of the pore channel to the top surface and the bottom surface. The pore diameter can also gradually expand from the bottom surface to the top surface. The peripheral surface of the structural ceramic body is wavy or zigzag.