A dental implant device for insertion into a bore defined in bone for use with a prosthetic tooth or dental appliance includes an abutment with a plurality of male keys disposed about the distal end of the abutment capable of being affixed to the prosthetic tooth or dental appliance, an implantable anchor having a proximal and distal end, a plurality of female keyways defined into the proximal end of the anchor, the keyways capable of coupling to the male keys of the abutment and thereby preventing relative rotation of the abutment and anchor, an interlocking thread helically defined around a longitudinal axis of the anchor, the thread being adapted to couple to the bore defined in the bone and means for coupling the abutment to the implant anchor.

A dental implant including a dental implant basic body extending along a longitudinal axis from an apical end to an opposite coronal end, which includes an anchoring part facing the apical end and intended to be anchored in bone of a patient, and a head part facing the coronal end and intended to form the basis on which a suprastructure is mounted. The anchoring part includes a shaft that is substantially cylindrical or that tapers toward the apical end in a cone-like manner. At least a portion of the shaft forms a bone tissue contact region, the outer surface forming a bone tissue contact surface. Coronally to the contact region a soft tissue contact region is arranged, the outer surface forming a soft tissue contact surface. The implant further includes nanostructures formed on the soft tissue contact surface which extend in at least two dimensions to 200 nm at most.

The present invention relates to a spike-fixing type implant and a method for implanting the same, the method enabling a dental root support to be inserted into the inside of an implant body in a state where the implant body, having a plurality of spikes protrusively formed thereon, is inserted in a dental root groove such that the diameter of the implant body is enlarged, and thus the spikes formed on the implant body are embedded in an alveolar bone and, finally, the implant body is firmly fixed in the dental root groove.

A dental framework has an integral body with an elongated, serpentine shape framework support extending substantially the length of the body. Uniquely designed dental crown receiving abutments each have a lower section with a larger average diameter than an upper section. This creates an adhesive receiving space between the abutments and the dental crowns which are installed on them. The abutments are also positioned such that gum composite material utilized following the installation of the framework and dental crowns can be inserted between adjacent abutments and the crowns to enhance the ultimate appearance of the mouth. A series of composite attaching spikes extend downward from the framework to ensure the framework remains secured within the composite material which is utilized.

Methods of manufacturing dental prosthesis/implants each to replace a non-functional natural tooth positioned in a jawbone of a specific pre-identified patient are provided. An example method includes the steps of receiving imaging data such as x-ray image data and surface scan data of a dental anatomy and/or a physical impression of the dental anatomy of a specific preidentified patient. The steps can also include forming a three-dimensional virtual model of at least portions of a non-functional natural tooth positioned in the jawbone of the specific pre-identified patient based on the imaging and surface scan data, virtually designing a dental implant based upon the virtual model, exporting the data describing the designed dental implant to a manufacturing machine, and custom manufacturing the dental implant for the specific patient.

The present invention relates to endosseous implants and in particular, to screw form dental implants for implanting within bone. The bone implant is configured to be a self-drilling bone implant that is adept at condensing, collecting and distributing bone along all of the implant's surface and within the implantation site, to significantly increase the bone implant contact surface. The implant is configured to have a coronal portion and a body portion that are continuous with one another. The coronal portion is configured to have a smaller overall diameter than the overall diameter of said body portion. The body portion is fit with threading that facilitates the self-drilling and bone collection properties when the implant is rotates in both the clockwise and counterclockwise directions.

A dental implant including an implant body having a top surface, and at least one non-annular cutaway portion longitudinally extending downwardly from the top surface along one side of the body and outwardly to the periphery, and a method for making the implant. The implant body preferably includes a body portion and a head portion integrally formed with the body portion, the body portion has a periphery and the head portion has a non-circular periphery, and the periphery of the head portion is smaller than the periphery of the body portion.

A dental implant includes an implant body with a coronally open cavity and at least one exit opening from an inside to the enossal outer surface. A thermoplastic element in the solid state is arranged in the cavity, and is brought into an at least partly flowable condition by applying a pressing force directed apically into the cavity, and mechanical oscillations. A portion of the flowable material of the thermoplastic element is pressed through the exit opening into surrounding bone tissue, when the implant body is arranged in an opening in the bone tissue and the enossal outer surface is in contact with the bone tissue. A re-solidification of the thermoplastic material after discontinuing the vibrations causes an anchoring through the connection between interpenetrated tissue and the implant body via the thermoplastic material penetrating both.

Dental prosthetic assembly (27) comprising a dental implant (2a, 2b) and a transfixed dental prosthesis (3). A connecting device (1) comprises: a lock (5) which has at least two radial wings (6a) and is mounted rotatably and retained in translation in one of dental implant (2a, 2b) or dental prosthesis (3), a retention cavity (15), provided on its periphery with protuberances (16a) extending radially towards the centre of the retention cavity (15), which is formed in the other of dental implant (2a, 2b) or dental prosthesis (3). The radial wings (6a) and the protuberances (16a) are configured and dimensioned in such a way as to cooperate by rotation of the lock (5) in order to keep the dental prosthesis (3) transfixed on the dental implant (2a, 2b), and in such a way as to allow the lock (5) and its radial wings (6a) to penetrate into the retention cavity (15) by a simple movement of axial translation.

A dental implant, including a generally cylindrical body having a proximal open end and a distal closed end and an externally threaded surface, a socket extending distally from the proximal end and terminating at a proximally facing shoulder and an internally threaded hole extending distally from the proximally facing shoulder and a curved portion formed between the proximally facing shoulder and the internally threaded wall.