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 maximized prepared bone surface, to integrate with a jawbone. Resultant implants are more durable and provide a better fit into the oral cavity. Various implant shapes and designs are disclosed. A dental implant may feature a plurality of bone spikes to serve as anchors for the implant in a patient's mouth. Multiple anchors lessen torques experienced by the implant during use. Ideally, the anchors will also project in different axes to maximize osseointegration and strength of the bond between bone and the implant.

A dental implant fixture as a fixture implanted in an alveolar bone to be an artificial tooth root includes a main body vertically extending long along a center axis, at least part of the main body being implanted in the alveolar bone, and a cutting face formed on an outer circumferential surface of the main body to secure a space for accommodating blood when the main body is implanted in the alveolar bone. The dental implant fixture does not apply excessive pressure to a cortical bone of an alveolar bone when being inserted into an implantation hole, and is capable of rapidly regenerating the alveolar bone by accommodating a large amount of blood inside the implantation hole.

A fixation facilitator mechanically associated with an intraosseous dental implant fixture.

A dental implant comprising a subperiosteal extension, said extension extending radially beyond a radius of a post of said dental implant. A device for mounting onto a dental implant configured to extend said dental implant to comprise a subperiosteal extension, said device extending radially beyond an interface between bone and said dental implant. A method of implanting a dental implant comprising elevating a mucoperiosteal flap at site of implantation, drilling a hole for inserting a dental implant comprising a subperiosteal extension, inserting said dental implant, and covering said subperiosteal extension with said mucoperiosteal flap. Related apparatus and methods are also described.

Provided is a method for making a biotransplant, comprising introducing autologous fibroblasts isolated from an oral mucosa of a patient into a platelet-rich fibrin (PRF) membrane using linear retrograde needle injection, where a needle is inserted into a thickness of the PRF membrane and a first puncture is made and then a series of punctures are made that are linearly aligned or arrayed with the first puncture and are spaced at a predetermined distance from a prior puncture. A method of treatment of a periodontal tissue and a biotransplant comprising a PRF membrane and autologous fibroblasts are also provided.

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.

The invention relates to an implant (1) comprising a support structure (5) which is prepared for anchoring, following the contours of the bone, in a jaw- and/or cranial bone (2), wherein at least one integrally attached post (7) protrudes from the support structure (5), said post being designed to have a finished denture anchored thereto and the post (7) having a base (9) that is formed out of the support structure (5) and is completed by a distal end region (10) with the interposition of a radially enlarged region (11). The invention also relates to a soft tissue displacement system (19) comprising an implant (1), a manufacturing process for a soft tissue displacement system (19) and a planning process for manufacturing an implant (1).

The present invention relates to a fixing piece firing device for a dental membrane, the device being capable of firing the fixing piece to fix the dental membrane that covers a graft site after bone graft during implant surgery, and of facilitating access into an oral cavity due to a tip part with a curved front end, thus enabling a quick and easy procedure without using a typical dental drill.

The present disclosure relates to a method of manufacture of a dental implant for a molar, including acquiring, structural data corresponding to bones of the facial skeleton, the bones of the facial skeleton being proximate the molar, selecting, as a dental implant fixation surface, a surface of the bones based upon a determined thickness of the bones, generating, based on the selected dental implant fixation surface, a contoured surface of the dental implant, and fabricating, based upon an instruction transmitted by processing circuitry, a bone plate extending from a buccal end of a cylindrical plate of the dental implant, the cylindrical plate having support lattices extending therefrom, at least one support lattice of the support lattices being arranged on a lingual end of the cylindrical plate, the cylindrical plate having an opening in a central region thereof, the opening being configured to receive a dental post.

The present invention relates to a customized or standardized bionic implant and its manufacturing, especially for dental applications. According to the first variant of the invention, the implant is characterized in that its single-component anchor possesses at least two bionic arms (2) tapering circumferentially, thereby creating at least one pointed (5) and/or linear (6) blade on each arm (2). According to the second variant of the implant, the single-component anchor possesses at least two bulging arms (2) forming at least one protrusion (4) on each of them. The manufacturing method depends on whether the implant is standardized, new and customized or is a modification of an implant selected from a digital library of standardized implants. Physical form of embodiments of the anchor may be printed in a 3D printer. In the case of customized implants, the process commonly comprise obtaining tomographic images of the biological target. In the case of designing a new implant, a panoramic curve/curves and panoramic surface are set and become the basis for the arms (2) of the implant's virtual anchor.