Provided is an implant configured to fit at or near a bone defect to promote bone growth, the implant comprising: a biodegradable polymer in an amount of about 0.1 wt % to about 20 wt % of the implant and an oxysterol in an amount of about 20 wt % to about 90 wt % of the implant. The implant has a high oxysterol load. Methods of making and use are further provided.

A bone void filler material is provided for sustained release of a therapeutic agent. The bone void filler material comprising a biodegradable matrix having ceramic cement beads comprising calcium sulfate, and ceramic particles disposed within the matrix. The ceramic cement beads are loaded with the therapeutic agent to cause sustained release of the therapeutic agent. Methods of use are also disclosed.

A bone void filler material is provided for sustained release of a therapeutic agent. The bone void filler material comprising a biodegradable matrix having ceramic cement beads comprising calcium sulfate, and ceramic particles disposed within the matrix. The ceramic cement beads are loaded with the therapeutic agent to cause sustained release of the therapeutic agent. Methods of use are also disclosed.

A bone void filler material is provided for sustained release of a therapeutic agent. The bone void filler material comprising a biodegradable matrix having ceramic cement beads comprising calcium sulfate, and ceramic particles disposed within the matrix. The ceramic cement beads are loaded with the therapeutic agent to cause sustained release of the therapeutic agent. Methods of use are also disclosed.

This invention relates to compositions and methods for promoting and/or accelerating bone regeneration, repair, and/or healing and, in particular, to compositions and methods of promoting bone regeneration, growth, repair, and/or healing using graft or scaffold materials. In exemplary embodiments, the disclosed compositions may be used to promote and/or accelerate bone regeneration by delivering a composition to a bone site, the composition comprising (a) a citrate component, (b) a phosphate component, and, optionally, (c) a particulate inorganic material. The citrate component and/or phosphate component is advantageously released from the composition at the bone site. The released citrate component may function to increase alkaline phosphatase activity and/or expression at the bone site, and the increased alkaline phosphatase activity and/or expression may release the phosphate component. The composition may be delivered in various forms, e.g., as a biodegradable scaffold.

A pharmaceutical formulation for use in a spinal fusion method, comprising a composition for forming a matrix, a kit comprising the composition, a pharmaceutical product obtainable from the pharmaceutical formulation, and an interbody spinal fusion cage containing the pharmaceutical formulation or the pharmaceutical product are described herein. The composition comprises at least a first matrix material precursor component and a second matrix material precursor component that are able to crosslink to form the matrix under appropriate conditions, a bioactive factor that is biologically active for stimulating bone formation between two vertebrae and for effecting or supporting spinal fusion. The bioactive factor is PTH, optionally a PTH fusion peptide. The bioactive factor is releasably incorporated in the matrix upon crosslinking of the matrix material precursor components.

A pharmaceutical formulation for use in a spinal fusion method, comprising a composition for forming a matrix, a kit comprising the composition, a pharmaceutical product obtainable from the pharmaceutical formulation, and an interbody spinal fusion cage containing the pharmaceutical formulation or the pharmaceutical product are described herein. The composition comprises at least a first matrix material precursor component and a second matrix material precursor component that are able to crosslink to form the matrix under appropriate conditions, a bioactive factor that is biologically active for stimulating bone formation between two vertebrae and for effecting or supporting spinal fusion. The bioactive factor is PTH, optionally a PTH fusion peptide. The bioactive factor is releasably incorporated in the matrix upon crosslinking of the matrix material precursor components.

The present invention relates to settable compositions for use in surgery. The invention also provides related compositions, including surgical kits and packages, as well as methods of making and using the settable compositions.

The present invention relates to settable compositions for use in surgery. The invention also provides related compositions, including surgical kits and packages, as well as methods of making and using the settable compositions.

An antibiotic-eluting article for implantation into a mammalian subject, produced by an additive manufacturing process wherein a polymeric material is concurrently deposited with a selected antibiotic. The additive manufacturing process may be a selective laser sintering process or a selective laser melting process or a selective heat sintering process or an electron beam melting process. The antibiotic-eluting article may be temporary or permanent orthopaedic skeletal component, an orthopaedic articulating joint replacement component, and/or an external hard-shell casing for an implantable device. One or more bone-growth-promoting compositions may be concurrently deposited with the polymeric material. The implantable device may be a cardiac pacemaker, a spinal cord stimulator, a neurostimulation system, an intrathecal drug pump for delivery of medicants into the spinal fluid, and infusion pump for delivery of chemotherapeutics and/or anti-spasmodics, an insulin pump, an osmotic pump, and a heparin pump.