Abstract: A spinal interbody device (IBD) includes a solid wall that at least partially defines a boundary of the IBD and a porous body connected to the solid wall. The porous body includes a plurality of sections that form at least a portion of both a superior and inferior bone interface side of the IBD. Each section of the porous body has a different porosity than an adjacent section such that the porosities increase toward a center of the IBD.

Abstract: A spinal interbody device (IBD) includes a solid wall that at least partially defines a boundary of the IBD and a porous body connected to the solid wall. The porous body includes a plurality of sections that form at least a portion of both a superior and inferior bone interface side of the IBD. Each section of the porous body has a different porosity than an adjacent section such that the porosities increase toward a center of the IBD.

Abstract: Implants including non-resorbable frameworks and resorbable components, as well as methods of use thereof are disclosed. The embodiments include different combinations of a non-resorbable framework (in some case structural and in other cases non-structural), and a resorbable component embedded within and/or around the framework (again, in some cases structural and in other cases non-structural). The disclosed implants provide an efficient means of providing structural support for the vertebral bodies post-implantation, as well as encouraging resorption of the implant and fusion of the associated vertebral bodies without negative side effects and/or failure, such as subsidence of the implant or cracking/fracturing of a portion of the implant when implanted.

Abstract: Implants including non-resorbable frameworks and resorbable components, as well as methods of use thereof are disclosed. The embodiments include different combinations of a non-resorbable framework (in some case structural and in other cases non-structural), and a resorbable component embedded within and/or around the framework (again, in some cases structural and in other cases non-structural). The disclosed implants provide an efficient means of providing structural support for the vertebral bodies post-implantation, as well as encouraging resorption of the implant and fusion of the associated vertebral bodies without negative side effects and/or failure, such as subsidence of the implant or cracking/fracturing of a portion of the implant when implanted.

Abstract: A method of forming a scaffold is disclosed herein. In some embodiments, a method of forming a scaffold includes dissolving a polymer in a solvent to form a polymer solution; adding additive precipitating agent to the polymer solution; precipitating and expanding the polymer from the polymer solution to form a scaffold; and removing the solvent from the scaffold. In some embodiments, prior to adding the precipitating agent, the method further comprising adding at least one of calcium phosphate or a bioactive additive to the polymer solution to form a mixture including the polymer solution and the at least one of calcium phosphate or bioactive additive.

Abstract: A spinal interbody device (IBD) includes a solid wall that at least partially defines a boundary of the IBD and a porous body connected to the solid wall. The porous body includes a plurality of sections that form at least a portion of both a superior and inferior bone interface side of the IBD. Each section of the porous body has a different porosity than an adjacent section such that the porosities increase toward a center of the IBD.

Abstract: A spinal interbody device (IBD) includes a solid wall that at least partially defines a boundary of the IBD and a porous body connected to the solid wall. The porous body includes a plurality of sections that form at least a portion of both a superior and inferior bone interface side of the IBD. Each section of the porous body has a different porosity than an adjacent section such that the porosities increase toward a center of the IBD.

Abstract: Implants including non-resorbable frameworks and resorbable components, as well as methods of use thereof are disclosed. The embodiments include different combinations of a non-resorbable framework (in some case structural and in other cases non-structural), and a resorbable component embedded within and/or around the framework (again, in some cases structural and in other cases non-structural). The disclosed implants provide an efficient means of providing structural support for the vertebral bodies post-implantation, as well as encouraging resorption of the implant and fusion of the associated vertebral bodies without negative side effects and/or failure, such as subsidence of the implant or cracking/fracturing of a portion of the implant when implanted.

Abstract: A spinal interbody device (IBD) includes a solid wall that at least partially defines a boundary of the IBD and a porous body connected to the solid wall. The porous body includes a plurality of sections that form at least a portion of both a superior and inferior bone interface side of the IBD. Each section of the porous body has a different porosity than an adjacent section such that the porosities increase toward a center of the IBD.

Abstract: Implants including non-resorbable frameworks and resorbable components, as well as methods of use thereof are disclosed. The embodiments include different combinations of a non-resorbable framework (in some case structural and in other cases non-structural), and a resorbable component embedded within and/or around the framework (again, in some cases structural and in other cases non-structural). The disclosed implants provide an efficient means of providing structural support for the vertebral bodies post-implantation, as well as encouraging resorption of the implant and fusion of the associated vertebral bodies without negative side effects and/or failure, such as subsidence of the implant or cracking/fracturing of a portion of the implant when implanted.

Abstract: In one embodiment, the present invention includes a method for repairing a cartilage defect including: preparing a cartilage defect by removing unwanted or damaged tissue; creating at least one perforation into or through subchondral bone, below and/or adjacent to the cartilage defect to induce the flow of bone fluid; allowing the bone fluid to bleed through the at least one perforation up into the cartilage defect to fill at least a portion of the cartilage defect; and applying a biomaterial into the defect to produce a clot for cartilage regeneration.

Abstract: In one embodiment, the present invention includes a method for repairing a cartilage defect including: preparing a cartilage defect by removing unwanted or damaged tissue; creating at least one perforation into or through subchondral bone, below and/or adjacent to the cartilage defect to induce the flow of bone fluid; allowing the bone fluid to bleed through the at least one perforation up into the cartilage defect to fill at least a portion of the cartilage defect; and applying a biomaterial into the defect to produce a clot for cartilage regeneration.

Abstract: Implants including non-resorbable frameworks and resorbable components, as well as methods of use thereof are disclosed. The embodiments include different combinations of a non-resorbable framework (in some case structural and in other cases non-structural), and a resorbable component embedded within and/or around the framework (again, in some cases structural and in other cases non-structural). The disclosed implants provide an efficient means of providing structural support for the vertebral bodies post-implantation, as well as encouraging resorption of the implant and fusion of the associated vertebral bodies without negative side effects and/or failure, such as subsidence of the implant or cracking/fracturing of a portion of the implant when implanted.

Abstract: A method of forming a scaffold is disclosed herein. In some embodiments, a method of forming a scaffold includes dissolving a polymer in a solvent to form a polymer solution; adding additive precipitating agent to the polymer solution; precipitating and expanding the polymer from the polymer solution to form a scaffold; and removing the solvent from the scaffold. In some embodiments, prior to adding the precipitating agent, the method further comprising adding at least one of calcium phosphate or a bioactive additive to the polymer solution to form a mixture including the polymer solution and the at least one of calcium phosphate or bioactive additive.