The invention provides composite materials that form a biocompatible and bioresorbable settable ceramic-forming composition, and that possesses high strength when set and other desirable mechanical properties. The composite materials may include additive materials that provide beneficial advantages in the handling and physical properties of the material. When a hydrated precursor, the composite material is capable of being injected through cannulas for placement in treatment sites. The composite material provided desirable handling properties and sets in a clinically relevant time period.

The invention provides composite materials that form a biocompatible and bioresorbable settable ceramic-forming composition, and that possesses high strength when set and other desirable mechanical properties. The composite materials may include additive materials that provide beneficial advantages in the handling and physical properties of the material. When a hydrated precursor, the composite material is capable of being injected through cannulas for placement in treatment sites. The composite material provided desirable handling properties and sets in a clinically relevant time period.

The invention provides composite materials that form a biocompatible and bioresorbable settable ceramic-forming composition, and that possesses high strength when set and other desirable mechanical properties. The composite materials may include additive materials that provide beneficial advantages in the handling and physical properties of the material. When a hydrated precursor, the composite material is capable of being injected through cannulas for placement in treatment sites. The composite material provided desirable handling properties and sets in a clinically relevant time period.

Biomaterials, implants made therefrom, methods of making the biomaterial and implants, methods of promoting cartilage, tissue, bone or wound healing in a mammal by administering the biomaterial or implant to the mammal, and kits that include such biomaterials, implants, or components thereof. For example, the composition may include or be combined with bone morphogenic proteins.

Biomaterials, implants made therefrom, methods of making the biomaterial and implants, methods of promoting cartilage, tissue, bone or wound healing in a mammal by administering the biomaterial or implant to the mammal, and kits that include such biomaterials, implants, or components thereof. For example, the composition may include or be combined with bone morphogenic proteins.

The disclosure relates to methods of making an osteoconductive polymer article for use as an orthopedic implant comprises steps of forming an article from a biocompatible, non-biodegradable polymer, the article comprising a non-flat surface with roughness Ra of at least 5 m; providing a dispersion of bioactive ceramic particles of particle size at most 10 m in a first solvent comprising a solvent for the polymer; coating at least the non-flat surface with the dispersion in at least one step; and rinsing the coated article with a second solvent being a non-solvent for the polymer to substantially remove the first solvent. Further disclosed is an osteoconductive polymer article for use as an orthopedic implant, which article is made from a biocompatible, non-biodegradable polymer and comprises a non-flat surface with roughness Ra of at least 5 m, wherein bioactive ceramic particles of particle size at most 10 m are partly embedded in the polymer at the surface of the article. The methods exhibit benefits in ease of modifying a surface layer with bioactive particles, applying mild conditions and not requiring use of further additives or post-treatments, or without significantly affecting bulk polymer properties, and result in an orthopedic implant article having particles adhering to the surface while still being accessible for interaction with surrounding tissue or fluid.

The disclosure relates to methods of making an osteoconductive polymer article for use as an orthopedic implant comprises steps of forming an article from a biocompatible, non-biodegradable polymer, the article comprising a non-flat surface with roughness Ra of at least 5 m; providing a dispersion of bioactive ceramic particles of particle size at most 10 m in a first solvent comprising a solvent for the polymer; coating at least the non-flat surface with the dispersion in at least one step; and rinsing the coated article with a second solvent being a non-solvent for the polymer to substantially remove the first solvent. Further disclosed is an osteoconductive polymer article for use as an orthopedic implant, which article is made from a biocompatible, non-biodegradable polymer and comprises a non-flat surface with roughness Ra of at least 5 m, wherein bioactive ceramic particles of particle size at most 10 m are partly embedded in the polymer at the surface of the article. The methods exhibit benefits in ease of modifying a surface layer with bioactive particles, applying mild conditions and not requiring use of further additives or post-treatments, or without significantly affecting bulk polymer properties, and result in an orthopedic implant article having particles adhering to the surface while still being accessible for interaction with surrounding tissue or fluid.

The disclosure relates to methods of making an osteoconductive polymer article for use as an orthopedic implant comprises steps of forming an article from a biocompatible, non-biodegradable polymer, the article comprising a non-flat surface with roughness Ra of at least 5 m; providing a dispersion of bioactive ceramic particles of particle size at most 10 m in a first solvent comprising a solvent for the polymer; coating at least the non-flat surface with the dispersion in at least one step; and rinsing the coated article with a second solvent being a non-solvent for the polymer to substantially remove the first solvent. Further disclosed is an osteoconductive polymer article for use as an orthopedic implant, which article is made from a biocompatible, non-biodegradable polymer and comprises a non-flat surface with roughness Ra of at least 5 m, wherein bioactive ceramic particles of particle size at most 10 m are partly embedded in the polymer at the surface of the article. The methods exhibit benefits in ease of modifying a surface layer with bioactive particles, applying mild conditions and not requiring use of further additives or post-treatments, or without significantly affecting bulk polymer properties, and result in an orthopedic implant article having particles adhering to the surface while still being accessible for interaction with surrounding tissue or fluid.

A composite dura substitute implant for implantation at a dura defect site having a porous layer that provides an osteoconductive scaffold for bony ingrowth, a porous layer that provides a scaffold for regeneration of collagen at a dura surface, and an intervening layer for preventing cerebrospinal leakage is disclosed. The composite dura substitute implant facilitates regeneration of dura mater and promotes osteointegration with bony tissue. Methods of manufacturing such an implant and methods of treatment using such composite dura substitute implants are further disclosed.

A composite dura substitute implant for implantation at a dura defect site having a porous layer that provides an osteoconductive scaffold for bony ingrowth, a porous layer that provides a scaffold for regeneration of collagen at a dura surface, and an intervening layer for preventing cerebrospinal leakage is disclosed. The composite dura substitute implant facilitates regeneration of dura mater and promotes osteointegration with bony tissue. Methods of manufacturing such an implant and methods of treatment using such composite dura substitute implants are further disclosed.