Systems, methods, and devices include techniques for generating and using a demineralized bone matrix (DBM)-gelatin matrix allograft material. The DBM-gelatin material can be used to form an implant (e.g., for sternal closure operations) and/or a gel (e.g., for wound/fracture treatment). A method for forming the implant or bone graft can include forming the DBM from an initial bone material; and mixing, in a solution, the DBM with a gelatin carrier to form a DBM-gelatin solution. The gelatin carrier can include an animal-based collagen, such as a porcine-based collagen or a bovine-based collagen. Additionally, the method of forming the bone graft can include performing a crosslinking reaction with the DBM-gelatin solution. The implant can be packaged in a sterile hydration container prior to use.

Systems, methods, and devices include techniques for generating and using a demineralized bone matrix (DBM)-gelatin matrix allograft material. The DBM-gelatin material can be used to form an implant (e.g., for sternal closure operations) and/or a gel (e.g., for wound/fracture treatment). A method for forming the implant or bone graft can include forming the DBM from an initial bone material; and mixing, in a solution, the DBM with a gelatin carrier to form a DBM-gelatin solution. The gelatin carrier can include an animal-based collagen, such as a porcine-based collagen or a bovine-based collagen. Additionally, the method of forming the bone graft can include performing a crosslinking reaction with the DBM-gelatin solution. The implant can be packaged in a sterile hydration container prior to use.

Compositions and blends of biopolymers and copolymers are described, along with their use to prepare biocompatible scaffolds and surgically implantable devices for use in supporting and facilitating the repair of soft tissue injuries.

Compositions and blends of biopolymers and copolymers are described, along with their use to prepare biocompatible scaffolds and surgically implantable devices for use in supporting and facilitating the repair of soft tissue injuries.

Disclosed herein is a technology for healing bone defects using bioactive silicate glass (BSG) and a 3D osteomimetic composite porous scaffold containing microspheres comprised of poly(lactide-co-glycolide) (PLGA).

Compositions useful as bone fillers or dental composites are provided which may include a sterilizing agent.

A medical implant comprising a plurality of biocomposite layers, each layer comprising a polymer and a plurality of uni-directionally aligned continuous reinforcement fibers. The medical implant is suitable for load-bearing orthopedic implant applications and comprises one or more biocomposite materials where sustained mechanical strength and stiffness are critical for proper implant function.

This invention relates to anti-microbial active particles, compositions and uses thereof for inhibiting bacterial growth on surfaces or devices. This invention further discloses methods of making such anti-microbial active particles.

A reinforced biocompatible scaffold facilitates integration of biological tissue. The reinforced scaffold comprises a porous biocompatible scaffold and an arrangement of at least one biocompatible filament embedded within and fixed to the biocompatible scaffold, and/or at least one biocompatible conduit embedded within and fixed to the biocompatible scaffold.

The present invention relates to a carrier composition for particulate and granular bone substitute materials which is a hydrogel comprising a mixture of ethylene oxide (EO)-propylene oxide (PO) block copolymers and silica nanoparticles embedded therein. The present invention further relates to a bone substitute material containing osteoconductive and/or osteoinductive particles or granules in addition to the novel carrier composition. Processes for producing the novel carrier composition and the novel bone substitute material are likewise provided in the context of the invention.