A method of forming an implant to be implanted into living bone is disclosed. The method includes the act of roughening at least a portion of the implant surface to produce a microscale roughened surface. The method further includes forming a nanoscale roughened surface on the microscale roughened surface. The method further includes the act of depositing discrete nanoparticles on the nanoscale roughened surface though a one-step process of exposing the roughened surface to a solution including the nanoparticles. The nanoparticles have a material having a property that promotes osseointegration.

Two part implant for attachment of artificial teeth comprising a base body having a bone contact surface and a soft tissue contact surface. The soft tissue contact surface is at least partially hydroxylated or silanated which results in an improved soft tissue integration.

The present disclosure relates to an implant surface modification treatment device including an internal electrode having a barrel-shaped structure and a surface on which a plurality of transmission parts are formed, an ultraviolet (UV) discharge vessel having a barrel-shaped structure that accommodates the internal electrode and has a gas-filled area filled with a discharge gas that serves as a UV light source, and an external electrode accommodating the UV discharge vessel inside thereof, wherein an implant fixture is placed inside the internal electrode to perform surface modification.

A body made of titanium or a titanium alloy having a topography for improved blood coagulation and/or cell attachment. The body is obtainable by a process that includes the subsequent steps of: a) etching at least a portion of the surface of the body with a first etching solution including a mineral acid, and b) etching the surface etched under a) with a second etching solution different than the first etching solution, the second etching solution including hydrofluoric acid.

Disclosed is a dental implant with a post element that can be inserted into a jawbone with a mounting element attached to the post element, and a dental element affixed to the mounting element, with the post element designed as a ceramic body of yttrium and/or aluminum oxide stabilized zirconium oxide. The dental implant should have an even additionally improved ingrowth or integration behavior during the osseous implant healing, compared with the prior art. The surface of the dental implant is provided with at least one partial area that has nanoscopic pores or an otherwise executed nanoscopic structure that has a depletion zone with a reduced yttrium and/or aluminum oxide element, compared to the internal volume

The present disclosure relates to a method for removing residual acid of implant that has been surface treated using acid, the method including thermal decomposition step of thermally decomposing and removing the acid remaining on the implant; base treatment step of treating the acid remaining on the implant with base, thereby neutralizing and removing the acid; and washing step of washing and removing the acid and the base remaining on the implant with washing water. According to the present disclosure, the acid remaining on the surface of the fixture can be effectively removed, and thus there is an effect of preventing the problem of bone loss that may occur near the placed implant.

A support element (S) for supporting implants (I), such as dental implants, the support element comprising a bar (S1) and a plurality of pins (S5) that are fitted to the bar (S1) and that are arranged parallel to one another, each pin (S5) defining a free end that is provided with reception means (S8) that are suitable for co-operating with the implant (S) so as to hold it on the reception means (S8) of the pin (S5), the bar (S1) including at least one mounting end (S4) for mounting the bar (S1) on another support device, thereby forming a support structure; the support element being characterized in that each pin (S5) is provided with a removal system (S9) for removing the implant (S) from the reception means (S8), without coming into contact with an exposed portion of the implant (S).

A process for the preparation of a topography for improved fibrin network formation and cell mineralization on at least a portion of a dental implant made of a binary titanium-zirconium alloy, the portion being destined to be embedded in a patient's jawbone and to be in contact with the jawbone via a bone-contacting surface, the process includes the subsequent steps of a) subjecting the bone-contacting surface of the dental implant to a sandblasting treatment, b) etching the sandblasted bone-contacting surface, and c) treating the sandblasted and etched bone-contacting surface with water or an aqueous solution for a duration of more than two days, during which nanostructures continuously grow on the bone-contacting surface, the nanostructures extending in at least two dimensions to 200 nm at most. The process is characterized in that the treatment of b) is carried out at a temperature from 40° C. to 60° C.

The present invention provides Dental implant configured to be inserted into a hole in jaw bone and to be at least partially situated in bone tissue when implanted, comprising: a coronal implant region, the surface of which is at least partly covered by an oxide layer with an average thickness in the range from 60 nm to 170 nm and has an average arithmetical mean height Sa in the range from 0.1 μm to 1.0 μm. Further provided is a component for dental applications, preferably dental abutment, wherein the surface of the component is at least partly covered by an oxide layer with an average thickness in the range from 60 nm to 170 nm and has an average arithmetical mean height Sa in the range from 0.05 μm to 0.5 μm and an implant system comprising the dental implant and the component. Method for forming a protective layer on the surface of an implantable or implant component, the method comprising a) applying a solution on the surface of component, the solution having a pH at 25° C. of 6.8 or less and b) drying the solution applied in step a) to form a protective layer on the surface of the component for dental applications. Finally, part of the present invention is an implantable or implant component having a protective layer obtainable as above and a use of such layer for storage.

The present invention provides a crystallographic orientation structured titanium alloy dental implant and manufacturing method thereof. The technique of modifying the surface structure (Ti/TiO.sub.2, amorphous) of the titanium alloy dental implant to form a [Ti/TiO.sub.2 anatase (215)] crystallographic orientation structure is applied in osseointegration field for improving activity of osteocyte, shortening the identification period of initial growth of osteocyte, accelerating the integration of human bone and the calcification of osteocyte tissue, with the advantage of healing wound fast, therefore being suitable for clinical treatment of dental implant surgery. The structure is relatively stable, uneasy to be worn and damage proof, not affected by the surface roughness, and assures the hydrophilicity of the adherence capacity of osteocyte. The structure features a specific crystal grains arrangement direction (crystallographic orientation) so as to increase cell activity, hydrophilicity, and biocompatibility.