An implant body having a coronal end and an opposing apical end, an outer surface and a compartment extending therein from a coronal end toward the apical end, the implant body including a gap between the compartment or spherical head portion and the outer surface.

A dental implant body includes a ceramics sintered body, and the ceramics sintered body is a porous body having blind/continuous holes formed from a surface of the ceramics sintered body and walls formed by the blind/continuous holes. The porosity of the blind/continuous holes may be 50±10%. Further, the diameter of the blind/continuous hole may be equal to or greater than 50 μm and equal to or smaller than 190 μm.

An abutment screw having a first hardness for use in affixing a dental prosthetic, having a second hardness less than the first hardness, to an abutment that itself is attachable to an implant in the mouth of a patient includes a head and a body. The body includes a smooth shank immediately proximate the head, and a threaded portion comprising a helical ridge that runs around its body, the helical ridge beginning at a point along the body distal the head portion. The head includes an upper surface, having a drive at a central portion thereof, and an underside surface having a convex radiused curvature extending until it meets the shaft, the convex radiused curvature being configured to conform to a corresponding concave curvature of a receiving portion of the prosthesis.

A multilayer crown includes an outer layer and an inner layer. The outer layer may be formed of a first polymeric material. The inner layer may be formed of a second polymeric material that is different from the first polymeric material. The inner layer may be arranged to contact a tooth so that the inner layer is located between the outer layer and the tooth.

The invention provides a dental implant system with a surface gradient microporous structure and a preparation method thereof. The dental implant system includes a non-threaded micro-cone cylindrical dental implant and an abutment, wherein the dental implant includes a microporous layer with a bionic bone trabecular structure and a base with extremely high density and mechanical strength. The dental implant system of the invention has both the precision of the internal structure and the bionic characteristics of the surface structure, which effectively improves the long-term stability after implantation, reduces the complexity of the processing process of the dental implant system, and can realize personalized and batch production.

A bone implant for at least partial insertion into a bone and/or cartilage. The bone implant is at least partially formed of a metal alloy of at least about 90 wt % of a solid solution or a rhenium and molybdenum alloy.

Tools, assemblies, devices, systems, and methods for easily mounting a crown to a titanium (Ti) base or custom abutment with a tool without having to pre-cement a mounting base to a crown and have to physically hold together the base to the crown until the cement is cured. The implant cementation assembly tool does allow the Ti base and crown to be cemented (pre-cemented) without being constantly held and done outside of the mouth. The embodiments can include a bottom (hard rod, such as plastic or metal) that goes through the Ti base and the crown. The embodiments can include a top that is either threaded to allow it to be screwed onto the hard rod or a top that has a hollow center that can slide over the hard rod and be clamped to the rod. A second embodiment uses a modified hemostat tool with lockable pivoting arms to clamp the crown to the Ti base to allow cement to become set

A dental implant for implantation in the jawbone for the purpose of fastening a superstructure. The implant includes an implant body that extends between a coronal and an apical end and which defines an enossal outer surface. The implant body defines a cavity that is open coronally as well as at least one exit opening from an inside to the enossal outer surface. An outer thread is shaped on the implant body. A thermoplastic element is moreover present in the solid condition and is arranged in the cavity or introducible into the cavity, wherein the thermoplastic element can be brought into an at least partly flowable condition by way of applying a pressing force, which is directed apically into the cavity, and mechanical oscillations and can be pressed through the at least one exit opening into surrounding tissue on account of the pressing force.

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 dental implant has an implant body made of diamond material, the implant body being provided with a bore hole that has at least one lateral dimension and a depth dimension, the lateral dimension and the depth dimension being mm sized. The bore hole is substantially formed by laser light being directed at the implant body to form said bore hole by softening said diamond material at an intended location of said bore hole. The bore hole is further defined by utilizing at least one metallic drilling tool to remove more of the diamond material after initial formation of the bore hole by said laser light. Preferably, the drilling tool has a cone shaped drilling head or a rectangular drilling head.