A prosthesis or implant device for use in joint or bone repair, or restoration of function. The prosthesis or implant device comprises a stem, in which a portion of the stem comprises non-overlapping lamellas around part or all of the circumference of the stem. Each lamella is connected to the external surface of the stem via a bending joint, which permits the space between the rest of the inner surface of the lamella and the external surface of the stem to decrease upon application of a force to the outer surface of the lamella. In addition, methods of treating a subject in need of joint replacement or bone repair using the prosthesis or implant device.

A dental prosthesis with a threaded crown on a post and core includes a dental implant, a post and core having a portion adapted to be inserted into the implant and another portion protruding from the implant, a screw and a crown, the implant being adapted to be fixed to a bone and the post and core being adapted to be fixed to the implant with a thread, the crown being fixed to the post and core with the screw, wherein the post and core provides a connection element between the implant and the crown, a separation area being provided between the area where the post and core is housed in the crown and the area where the post and core is housed in the implant, and wherein the portion of the post and core protruding from the implant does not feature a diameter increase.

An implant device configured to be at least partially in contact with bone on implantation has an improved osteoinductive feature to enhance new bone formation. The implant device has one or more bone growth surfaces extending from a structurally solid feature of the implant device. The one or more bone growth surfaces are configured to mimic adult trabecular bone by having trenches, grooves or surface recesses or prominences exhibiting numerous structural elements or walls not perpendicular to the surface that are non-coplanar or arched extending 20 to 500 microns in depth having an increasing inclination from the surface extending inwardly and not parallel to opposing or adjacent walls forming a random or non-random network. The one or more bone growth surfaces configured to mimic trabecular bone have discernable nano features on the structural elements or walls exhibiting nano scale features of less than 200 nano meters within the network.

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 abutment (3) for a modular dental implant (1) wherein the modular dental implant (1) comprises a main part (2) that can be anchored in a jawbone and is made of a metal material suitable for implants; and comprises the abutment (3), which is intended to be connectable to the main part (2) of the modular dental implant (1).

The abutment (3) is made of a ceramic material suitable for implants (3). The surface (31) in a contact region (5) of the abutment (3) is intended to contact a surface (21) in a contact region (5) of a main part (2), or to lie on the surface (21) in the contact region (5) of the main part (2), when the modular dental implant (1) is in an assembled state. The surface (31) of the abutment (3) in the aforementioned contact region (5) of the abutment (3) is processed in such a way that the surface (31) has a roughness average Ra which, when the modular dental implant (I) is in operation, prevents damage, in particular the removal of material, by the abutment (3) to the surface (21) of the main part (2) in the aforementioned contact region (5) of the main part (2).

Methods for forming micro- and/or nano-structures on the surfaces of a device and devices made thereby. The methods include exposing the surfaces of the device having an initial microstructure to an oxidizing environment at a first elevated temperature so as to form a first oxide scale on the device surfaces, exposing the first oxide scale to a reducing agent at a second elevated temperature so as to convert or partially convert the first oxide scale into a composite scale that includes a second oxide and a first metal, and exposing the composite scale to a dissolution agent that selectively dissolves part or all of the second oxide so as to yield a porous surface layer that includes the first metal.

Provided are a dental implant with a nano bacteriostatic structure ring at a transgingival part and a machining method thereof. The transgingival part of the dental implant has a three-level micro-nano composite structure, and the three-level micro-nano composite structure endows a surface of the transgingival part of the implant with functions of promoting adhesion and proliferation of a gingival fibroblast and a gingival mesenchymal stem cell and inhibiting adhesion and growth of various oral bacteria. A preparation method thereof comprises: firstly, injecting bioactive, wear-resistant or corrosion-resistant C, N, Ca and P elements into the transgingival part of the dental implant by a plasma injection method; and then, preparing the three-level micro-nano composite structure at a part in which the elements are injected.

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 device includes an implant with a threaded portion and a drilling portion and a positioning hole respectively formed at two ends of the implant. Pores are recessed into a surface portion of the implant. Each pore has a peripheral wall. The peripheral wall and the surface portion meet an end edge. Adjacent end edges and peripheral walls are joined to cause adjacent pores to communicate one after another, thereby forming communicating channels. When the implant is fastened to a target part, cells derived from the target part are quickly attached to the end edges and enter the channels to attain a smooth adhesion and proliferation. The proliferated cells climb between the pores and channels and become linked to hold the implant firmly and enhance the combination between the implant and the target part, thereby shortening the convalescence period of the target part.

The present invention provides a mid-gingival dental implant system that includes a dental implant having a threaded body portion and a superstructure extending from a coronal surface of the threaded body portion. The superstructure includes two O-ring housings for housing deformable O-rings. The mid-gingival system can also include two screws. One for screw retained final components and one for cement retained final components.