Abstract: A medical positioning bracket is described that provides users with the ability to attach and secure multiple bone tunnel drill guides into a single working unit. Users can manipulate each drill guide independently and lock the drill guides at desired locations relative to one another to achieve precise bone tunnel angles and locations.

Abstract: Methods for developing a decellularized tissue and biomaterials for use as biomimetic grafts or in vitro cellular scaffolds formed with the decellularized tissue are described. The biomaterials are particularly well suited for use as an intervertebral disc graft. The decellularized tissue is formed from an intervertebral disc source tissue and can be substantially decellularized and substantially free of potential immunogenic material (e.g., DNA and RNA), while maintaining ECM materials including both glycosaminoglycan and collagen.

Abstract: Biocompatible biomimetic materials that exhibit desirable mechanical properties while also encouraging cell ingrowth and proliferation are described. The biomaterials include a multi-layer laminate of three or more decellularized aligned collagen tissues. The individual layers are aligned with one another in an angle-ply arrangement, with the collagen of each layer aligned at an angle to the collagen of the adjacent layer. The biomaterials are useful as collagenous graft materials such as a patch for a hernia in an annulus fibrosus or grafting materials for repair of tendons, ligaments, cartilage and other musculoskeletal tissues.

Abstract: Methods for developing a decellularized tissue and biomaterials for use as biomimetic grafts or in vitro cellular scaffolds formed with the decellularized tissue are described. The biomaterials are particularly well suited for use as an intervertebral disc graft. The decellularized tissue is formed from an intervertebral disc source tissue and can be substantially decellularized and substantially free of potential immunogenic material (e.g., DNA and RNA), while maintaining ECM materials including both glycosaminoglycan and collagen.

Abstract: The present invention relates to a flowable bone graft material including an inorganic composition comprising calcium phosphate having a particle size of about 100 ?m to about 1,000 ?m, bioactive glass, and one or more biocompatible polymers comprising carboxymethyl cellulose and a fluid.

Abstract: Methods for developing a decellularized tissue and biomaterials for use as biomimetic grafts or in vitro cellular scaffolds formed with the decellularized tissue are described. The biomaterials are particularly well suited for use as an intervertebral disc graft. The decellularized tissue is formed from an intervertebral disc source tissue and can be substantially decellularized and substantially free of potential immunogenic material (e.g., DNA and RNA), while maintaining ECM materials including both glycosaminoglycan and collagen.

Abstract: Biocompatible biomimetic materials that exhibit desirable mechanical properties while also encouraging cell ingrowth and proliferation are described. The biomaterials include a multi-layer laminate of three or more decellularized aligned collagen tissues. The individual layers are aligned with one another in an angle-ply arrangement, with the collagen of each layer aligned at an angle to the collagen of the adjacent layer. The biomaterials are useful as collagenous graft materials such as a patch for a hernia in an annulus fibrosus or grafting materials for repair of tendons, ligaments, cartilage and other musculoskeletal tissues.

Abstract: The present invention relates to a flowable bone graft material including an inorganic composition comprising calcium phosphate having a particle size of about 100 ?m to about 1,000 ?m, bioactive glass, and one or more biocompatible polymers comprising carboxymethyl cellulose and a fluid.

Abstract: A medical positioning bracket is described that provides users with the ability to attach and secure multiple bone tunnel drill guides into a single working unit. Users can manipulate each drill guide independently and lock the drill guides at desired locations relative to one another to achieve precise bone tunnel angles and locations.

Abstract: A nucleus pulposus replacement is described that includes a containment balloon that can sequester synthetic and/or tissue engineered fill material(s) in the nucleus pulposus region of the IVD thus mitigating migration and expulsion of the fill materials. The containment balloon can be formed of a biocompatible material that includes the structural proteins elastin and collagen. The containment balloon is joined to a closure device that can be used to deliver a fill material, e.g., a hydrogel, to the interior of the containment balloon following implantation of the replacement device in the intervertebral disc area.