The present disclosure is relates to a one-piece dental implant including a first portion and a second portion. The first portion has a central axis, a bony portion, and a gingival portion. The bony portion is connected to the gingival portion. The second portion has a connection portion and a trimming portion. A cross-sectional area of the trimming portion is larger than a cross-sectional area of the gingival portion of the first portion in a direction perpendicular to the central axis L. The trimming portion has a plurality of side surfaces and a clamping portion. The at least one side surface of the trimming portion is asymmetric with other side surfaces, and the side surface gradually expanding upward. The cross-sectional area of the trimming portion asymmetrically and gradually increases upward. The clamping portion is disposed on an upper portion of the trimming portion.

A dental implant supported on the cortical bone is implanted in the socket from which the tooth was extracted, if this hole still exists, or in the remaining socket when the tooth was extracted some time before, or alternatively in a hole made for placement of the implant, at cortical bone level, and externally, between the cortical bone and the gingiva, slightly embracing the mandible and the maxilla.

In one embodiment, in order to enhance the fixation and implant lifetime vascularization, the implant of the present disclosure for fitting in an intraosseous zone of a dental socket includes a plurality of raised platforms with a flat top such that said tops form an external surface of the implant for contacting with the intraosseous zone and the spaces between said platforms form a network of channels for revascularisation fluid flow with capillarity properties.

A dental implant, having a central cavity and a strength adjusting structure, is provided. A first opening of the central cavity and a second opening of the strength adjusting structure are both located on a top surface of the dental implant. The strength adjusting structure is located between the central cavity and a side surface of the dental implant. A ratio of a first depth of the strength adjusting structure in a length direction of the dental implant to a second depth of the central cavity in the length direction of the dental implant is greater than 0 and less than or equal to 0.8.

An implant fixture is disclosed. The implant fixture contains an elongated shaft section, and a head section, wherein the head section contains at least one concave area for bone growth therein.

An anatomical dental implant arranged to be implanted in a naturally occurring cavity of the jawbone, the implant comprising at its apical side a root part arranged to anchor the implant in the cavity and at its occlusal side an abutment part arranged for supporting a dental prosthetic element, wherein the root part comprises an outer surface arranged to come into contact with the cavity walls, and wherein the root part comprises an outer section adjacent to the outer surface of the root part, wherein the outer section of the root part is arranged to deform plastically upon insertion of the root part into the cavity such that the root part substantially conforms to the shape and size of the cavity.

A jaw bone anchor for threadless engagement with a drilled jaw bone hole, the jaw bone anchor having an apical side, a coronal side, and having a root section, the jaw bone anchor including an inner core having a longitudinal extension along the root section, an outer osso-integrative shell layer that is arranged around the inner core, and a plurality of radially- extending bone engaging elements, the radially-extending bone engaging elements extending from the inner core, traversing and protruding from the outer osso-integrative shell layer.

A dental implant with a specialized thread arrangement is disclosed. The dental implant includes a cylindrical upper section and a tapered lower section coupled to the cylindrical upper section. A helical thread is located on the exterior surface of the cylindrical upper section and the tapered lower section. A path is defined by the helical thread. The helical thread has a section on the exterior surface of the cylindrical body section and a section on the tapered body section. A cutting tooth is formed on the helical thread where the thread section on the cylindrical body section transitions into the thread section on the tapered body section. The cutting tooth allows minimal torque to be applied to create stability of the implant by cutting into the dense part of the bone.

A dental implant for supporting periodontal tissue and the supporting bone is provided. The dental implant includes an implant member with inner canal for insertion into a periodontal bone socket, and an anchoring assembly. The anchoring assembly includes a first fastening element and radially equidistant cylindrical members. The first fastening element engages the implant member within the hollow axial cavity. The root section includes through-holes for radially and forcibly sliding the cylindrical members through them. When the first fastening element apically advances within the hollow axial cavity, the cylindrical members generate an anchoring force to anchor the dental implant.

The invention relates to a method for a computer-implemented method for configuring a fastening channel through a dental restoration for fastening a retaining means retaining the dental restoration. The method comprises receiving a 3D digital restoration model of the dental restoration with an artificial tooth and a definition of an implant. A relative positioning of the dental restoration relative to the implant is determined. A position of the fastening channel extending from the implant through the artificial tooth is determined. In case the position of the fastening channel violating a set of one or more pre-defined positioning criteria. The position of the fastening channel is automatically adjusted by angulating the fastening channel such that the positioning criteria are satisfied.