The invention is a fastener for medical or dental use which requires minimal preparation of a site in bone. According to one embodiment the fastener includes a shank and a head having an aperture with a torque-receiving aperture such as a threaded hole or a polygon such as a hex-sided hole. The other end of the shank is a blunt or a sharp point. Another embodiment includes a radially spaced apart series of strakes each having a linearly spaced apart series of barbs. An alternative embodiment includes on the shank a radially spaced apart series of linear arrays of barbs emerging from the shank itself. The linear spacings may be staggered from one radial line to the next so that as a whole the barbs are arranged into one or more continuous helicies.

The present disclosure concerns a subperiosteal dental implant for receiving at least one replacement tooth of a patient, the subperiosteal dental implant comprising an implant frame superposable to at least a section of a jaw hone of the patient, the implant frame having a bone-facing surface at least partially contacting the jaw hone of the patient when the implant frame is superposed thereto, and an opposed gum-facing surface, the implant frame having at least a section along which a cross-section profile includes a base defining at least partially the bone-facing surface and at least partially the gum-facing surface, a ridge protruding from the base and defining at least partially the gum-facing surface, and a first shoulder and a second shoulder that are both defined on the gum-facing surface of the base, each one being located on a respective side of the ridge.

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 is directed to a new dental implant and associated parts that allow for insertion in narrow areas of the alveolar bone. Characteristics of the body of the implant allow for comfortable insertion in narrow bone clefts provided by its smooth narrow sections. The implant provides an alternative to complex and time consuming surgical processes involving bone regeneration and/or grafting.

Dental implant, having a central body (1) with a substantially conical or frustoconical shape and having, extending from the end with a larger cross-section, a connection seat (701) able to receive a stump pin; this central body (1) is provided with a blade (2) positioned in a longitudinal mid-plane of said central body (1) and has a length so as to protrude beyond the end of said central body (1) which has a smaller cross-section; said central body (1) and the blade (2) are able to give the implant a substantially wedge-like form able to expand the bone during insertion.

The present disclosure relates to a ceramic structure for dental application, preferably dental restoration, process for obtaining it and its uses. The process now disclosed comprises computer-controlled machining (CNC), particularly by milling, to obtain a ceramic structure, for example dental covers, which reach thicknesses between 0.05 and 0.4 millimeters.

The invention relates to a method for manufacturing at least one bone anchor and a corresponding drilling template, wherein the bone anchor has an anchor plate which is to be fixed to the surface of a bone by means of one or several screws having a screw head. The anchor plate thus has a bone side which is to connect to the surface of the bone and a free side which is opposite to said bone side. Further, the invention concerns a method for manufacturing a drilling template making it possible to make bore holes in the bone at predetermined positions and to screw the bone anchor to said bone according to predetermined orientations.

The present disclosure relates to a ceramic structure for dental application, preferably dental restoration, process for obtaining it and its uses. The process now disclosed comprises computer-controlled machining (CNC), particularly by milling, to obtain a ceramic structure, for example dental covers, which reach thicknesses between 0.05 and 0.4 millimeters.

A dental implant has a substantially cylindrical configuration and a pair of wing members projecting outwardly from diametrically opposite side wall portions of the implant. The wing members have a substantially right triangular configuration with one leg of each right triangle effectively connecting the wing member to the body of the implant, the other leg of the right triangle extending outwardly from the body of the implant at an orientation that is perpendicular to the longitudinal axis of the implant body, and the hypotenuse side of the right triangle being radiused so as to promote osseointegration. In addition, two winged implants may be connected together by means of a connecting bar or plate. In accordance with this dual implant, the wing members are only provided upon the laterally external side wall portions of each implant while the oppositely disposed internal portions of each implant are integrally connected to the intermediary connecting bar or plate. The undersurface of the connecting bar or plate is likewise radiused so as to promote osseointegration.

A dental implant device configured as a single, solid, unitary structure, including a body portion, multiplicity of wedging edge portion, and an apical end portion, wherein the implant device is configured to be installed in a patient's mandibular or maxillary bone. The apical end portion is configured to be beveled on a multiplicity of sides. The apical end portion may also include a joining surface, the joining surface has a saw-like serration pattern, a generally jagged pattern, or a smooth pointed edge to aid in locking the implant device to the maxilla or mandible to achieve initial stability and mechanical retention. The apical end portion may further include a multiplicity of generally circular holes to generally aid bone growth and facilitate stronger osseointegration. The dental implant comprises a biocompatible material including zirconia or titanium alloy. A minimum of 5 mm of the apical end portion would be inserted into the bone.