A biocompatible structure includes a scaffold obtained from a 3D structure. The 3D structure includes base layered structures, each of which includes at least a first layer and a second layer surrounded by the first layer. The first layer includes at least one of first, second and third media. The second layer includes at least another of the first, second and third media. The first medium comprises bone particles. The second medium comprises a polymer dissolvable in a first solvent. The third medium comprises solid particulates dissolvable in a second solvent different than the first solvent. The 3D structure is treated with the second solvent to dissolve the solid particulates so as to form pores at positions of the solid particulates therein, thereby resulting in the scaffold having a porosity adjustable by sizes of the solid particulates and concentration of the solid particulates in the 3D structure.

A transfer device designed to extract an amorphous or semi-solid structure, tissue, or construct from supporting media while maintaining the spatial integrity/organizational architecture thereof. The transfer device can include a controller, an actuator assembly, a plunger, and a needle. The controller can move the transfer device and the plunger independently.

A bone regeneration material has a cotton-wool like structure formed of a plurality of electrospun fibers that contain bound BMP-2 through β-TCP binding peptide. The electrospun biodegradable fiber contains 25-65 vol % of β-TCP particles distributed in the fiber such that a portion of the β-TCP particles is exposed on a surface of the electrospun fiber and the remaining portion of the β-TCP particles is buried in the fiber. β-TCP binding peptides that are fused with BMP-2 are bound to the β-TCP particles so that BMP-2 is tethered to β-TCP particles on the surface of the fibers. Upon implantation of the bone regeneration material in a bone defect site of a human body, BMP-2 that are tethered to β-TCP particles on the surface of the bone regeneration material promotes proliferation and differentiation of cells at the bone defect site.

A bone augmentation composition and a method for making the bone augmentation. The method including hydrating an allograft comprising cortical fibers with a cell culture media, seeding the hydrated allograft with a solution of human stem cells, and culturing the stem-cell seeded allograft to grow a population of the stem cells in the seeded graft prior to freezing the bone augmentation composition for storage.

A method for producing a composite demineralized bone matrix composition using a one-step process is described. The composite demineralized bone matrix composition is produced from the biologically-derived bone. In addition, the composite demineralized bone matrix composition contains bone minerals according to the original composition proportion in the bone and may provide a bone mineral content condition that is closest to that in an environment in which in vivo bone formation occurs. In addition, the composition contains a bone morphogenetic protein (BMP-2), and thus enables a stable and excellent bone formation effect to be derived.

The present disclosure describes methods of treating a ligament injury with ligament grafting.

The present invention relates to methods for producing biphasic calcium phosphate materials using chemical processing methods including exposure to peroxides. The resulting materials exhibit an osteoinductive needle-like surface morphology and are useful as artificial bone grafts.

Multiple component grafts are provided for treatment of tissue defects and comprise two or more components, each of which is a tissue-derived matrix and at least two of which are derived from different types of tissue. For example, a first component may be a matrix derived from cartilage tissue such as cartilage fibers with or without viable cells, cartilage particles with or without viable cells, or combinations of any two or more such cartilage-derived matrices. A second component may be a matrix derived from bone tissue such as mineralized or demineralized cortical bone fibers, viable cancellous bone matrix (e.g., cryopreserved or lyophilized chips, particulates, powder, sheets, putty, flowable fluid, etc.), demineralized or demineralized cancellous bone matrix (chips, particulates, powder, sheets, putty, flowable fluid, etc.), or combinations of any two or more of such bone-derived matrices. Also provided are methods for making and using such multiple component grafts.

A particle comprising hydroxyapatite, β-tricalcium phosphate, α-tricalcium phosphate, and/or bioactive glass is provided. The particle can be useful in bone graft compositions further comprising a carrier. The composition can include a quadphasic particle having hydroxyapatite, β-tricalcium phosphate, α-tricalcium phosphate, bioactive glass, and a carrier. The particle can have a size in the range of 50 microns to 2.5 mm. A method of repairing a bone defect is also provided. The method can include a step of applying the bone graft composition to a subject having the bone defect, such as a spinal bone defect. The subject receiving the bone graft composition can be a mammal, namely a human, pet, or domestic animal.

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.