A multifunctional prosthetic component developed to have multiple functions within the conventional or digital workflow, in which a temporary or permanent prosthesis is made for a dental rehabilitation unit that is cemented or screwed on a dental implant. Thus, the component has a geometry that allows it to be used as a conventional closed tray transfer, conventional open tray transfer, scanbody, and temporary abutment, basically including three main regions: a lower region, an intermediate region and an upper region, being also able to cooperate with a positioner cap.

Customized dental implants feature enhanced osseointegrable qualities by manufacturing the implant post with osseointegrable material and preparing a larger post body, including a portion to cover a prepared bone surface, to integrate with a jawbone. Resultant implants are more durable and provide a better fir into the oral cavity. Various implant shapes and designs are disclosed.

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 biological tissue rootage face (30) capable of closely bonding to a biological tissue (H, S) is composed of a biocompatible material and has numerous fingertip-shaped microvilli (41). The microvilli (41) have tip diameters in the order of nanometers. An implant (1) has the biological tissue rootage face (30) on a surface (11, 24) configured to root into a biological tissue (H, S). In a method for forming the biological tissue rootage face (30), a surface of a biocompatible material is subjected to laser nonthermal processing carried out by emitting a laser beam in air, to form numerous fingertip-shaped microvilli (41). The laser beam is a laser beam of an ultrashort pulse laser.

Dental implants, dental abutments, and dental systems are disclosed. A dental implant can include an implant body having a longitudinal axis, a coronal end, and an apical end. An internal bore can be provided within the implant body, and can have a coronal end, adjacent to the coronal end of the implant body, and an apical end. The internal bore can include a first internally facing surface, extending from the coronal end of the internal bore towards the apical end of the internal bore, at least a portion of which tapers inwardly towards the apical end of the internal bore. The internal bore can further include an internally threaded portion positioned between an apical end of the first internally facing surface and the apical end of the internal bore. A dental abutment can be configured to engage with the dental implant.

A tantalum-titanium alloy powder that is highly spherical is described. The alloy powder can be useful in additive manufacturing and other uses. Methods to make the alloy powder are further described as well as methods to utilize the alloy powder in additive manufacturing processes. Resulting products and articles using the alloy powder are further described.

A ceramic implant which has a ceramic, endosseous surface region that is intended to be embedded into the bone tissue and that is made of a ceramic material. The surface region has at least one first zone having a surface modification, in which first zone the surface is roughened or porous, and at least one second zone, in which the surface is not roughened or porous.

The present invention relates to a dental prosthesis molding block (10) for producing a dental prosthesis part. The block comprises an inner material (13) that is at least partially surrounded by an outer material (14), the hardness of which differs from the hardness of the inner material (13). The inner material (13) forms part of a first surface (11) of the dental prosthesis molding block (10). The invention further relates to a method for producing a dental prosthesis part. In said method, a dental prosthesis molding block (10) is provided, and the dental prosthesis part is produced by removing material from the dental prosthesis molding block (10) using a CAD/CAM process. In doing so, a pin having a self-tapping external screw thread is created.

Described herein is a method of preparing a bone graft product, comprising computer-guided precision cutting an unshaped piece of bone from a human cadaver or a bovine animal to provide a shaped piece of bone having a predetermined shape that is determined by a human being using computer-aided design. Bone graft products prepared using this method and methods of grafting these products are also disclosed.

A process for preparing a body having an osseointegrative topography formed on its surface. The process includes the steps of providing a primary body made of a titanium-zirconium alloy containing 13 to 17 wt-% of zirconium, sandblasting the primary body, and etching the sandblasted primary body with an etching solution including hydrochloric acid, sulfuric acid and water at a temperature of above 80 C. to obtain the body, said etching being performed for a duration of 350 seconds at least.