A top piece for a corresponding pin-shaped dental implant with a platform, which features a first platform surface and a second platform surface, a retention pin placed onto the first platform surface, for mounting of a mesostructure, a connecting pin for connecting the platform with a blind bore of a pin-shaped dental implant corresponding to the connecting pin, while in a first version, an edge of the platform is bulged in a direction oriented away from the connection pin, and in a second version, a diameter of the platform is large enough, at least in a part of a total angular area that, where the top piece is connected to the corresponding pin-shaped dental implant, in a view from above onto the second platform surface, the platform protrudes over the corresponding pin-shaped dental implant.

A biocompatible metal implant is provided with a treated surface subject to abrasive mechanical treatment, acid treatment, and sodium treatment, where the biocampatible metal implant treated surface has a macroporosity in the form of cells having dimensions of the order of 50 m to 250 m, the cells having pores of from 1 m to 50 m, and pores with a size of less than a micrometer, homogeneously over the whole of the treated surface, the treated surface having a surface roughness Ra of greater than or equal to 1.90 m.

An implant system and a method of forming the implant system including an implant to be implanted into living bone. The implant includes titanium. The implant includes a first surface geometry on a first portion of a surface of the implant and a second surface geometry on a second portion of the surface of the implant. The first surface geometry includes at least a submicron topography including tube-like structures and the second surface geometry includes a first micro-scale topography, a second micro-scale topography superimposed on the first topography, and a submicron topography superimposed on the first and second micro-scale topographies, the submicron topography including the tube-like structures.

An implant system and a method of forming the implant system including an implant to be implanted into living bone. The implant includes titanium. The implant includes a first surface geometry on a first portion of a surface of the implant and a second surface geometry on a second portion of the surface of the implant. The first surface geometry includes at least a submicron topography including tube-like structures and the second surface geometry includes a first micro-scale topography, a second micro-scale topography superimposed on the first topography, and a submicron topography superimposed on the first and second micro-scale topographies, the submicron topography including the tube-like structures.

An implant for implantation into bone tissue includes an elongated body having an outer surface. The outer surface hast least one thread. The thread makes a number of turns around the body of the implant and includes a root, a flank and a crest. The root and a segment of the flank have a roughened portion compared to the crest. A method of forming an implant having a threaded outer surface including a root, a flank, and a crest includes treating the threaded outer surface at only the root and a portion of the flank while the crest remains untreated.

An implant system and a method of forming the implant system including an implant to be implanted into living bone. The implant includes titanium. The implant includes a first surface geometry on a first portion of a surface of the implant and a second surface geometry on a second portion of the surface of the implant. The first surface geometry includes at least a submicron topography including tube-like structures and the second surface geometry includes a first micro-scale topography, a second micro-scale topography superimposed on the first topography, and a submicron topography superimposed on the first and second micro-scale topographies, the submicron topography including the tube-like structures.

An implant for implantation into bone tissue includes an elongated body having an outer surface. The outer surface has at least one thread. The thread makes a number of turns around the body of the implant and includes a root, a flank and a crest. The root and a segment of the flank have a roughened portion compared to the crest. A method of forming an implant having a threaded outer surface including a root, a flank, and a crest includes treating the threaded outer surface at only the root and a portion of the flank while the crest remains untreated.

An implant system and a method of forming the implant system including an implant to be implanted into living bone. The implant includes titanium. The implant includes a first surface geometry on a first portion of a surface of the implant and a second surface geometry on a second portion of the surface of the implant. The first surface geometry includes at least a submicron topography including tube-like structures and the second surface geometry includes a first micro-scale topography, a second micro-scale topography superimposed on the first topography, and a submicron topography superimposed on the first and second micro-scale topographies, the submicron topography including the tube-like structures.

The invention relates to a method for surface treatment of a biocompatible metal material, such as an implant, which comprises the following consecutive steps: i) abrasive mechanical treatment of the surface of said material using abrasive calcium phosphate grains, such as a mixture of hydroxyapatite and tricalcium phosphate; ii) acid treatment by hot dipping of said material in a bath comprising sulphuric acid and hydrochloric acid, followed by at least one rinse with demineralised water; iii) sodic treatment by hot dipping of said material in a soda bath followed by at least one rinse with demineralised water and drying in hot air. The implant thus treated has a surface with increased roughness with a triple level of porosity (macro-, micro- and nano-porosity) as well as improved hydrophilic properties. The method can be used for implants made of titanium alloys, such as the TA6V ELI alloy.

A method and system for bone tissue regeneration in association with a predetermined dental bone structure obtains a computerized tomography scan of a dental bone structure on which to regenerate bone tissue. A three-dimensional model digitally represents the dental bone structure. A treatment plan corresponding to said three-dimensional model and a design order permit forming an occlusive barrier for covering the portion of the dental bone structure whereupon to regenerate bone tissue. An occlusive barrier from a biocompatible material and an osteoconductive material form flesh and regenerated bone tissue via osteoconduction. The occlusive barrier includes irrigation channels for permitting flushing of said interior volume and may be formed of pieces printed for forming a volume to regenerate bone tissue. The occlusive barrier may be subjected to a heat treatment for alleviating molecular stress and increasing occlusive barrier ductility and strength. Surface sandblasting treatment forms surface porosity promoting osteoconduction.