Embodiments of the disclosure relate to implantable objects and guiding devices, as well as recipient site preparation instruments, bone-implantable materials, and methods of fabrication and use thereof.

An anatomically-contoured subperiosteal jaw implant includes an annular-shaped baseplate and internal support arms corresponding to a location of a plurality of height-adjustable posts. The baseplate is configured for placement over the alveolar ridge of a mandible or maxilla bone and creates a plurality of internal apertures within the baseplate to minimize the impact on the alveolar ridge and improve re-attachment of bone and soft tissue revascularization after implant insertion. The baseplate is attached with the bone via a series of screws inserted through screw holes uniquely positioned throughout the baseplate based on individual anatomical models of a patient receiving the implant, and the height-adjustable posts are also shaped for partial insertion into the bone to reduce the height of the posts and attached dental component while also improving retention of the implant. The support arms absorb stress on the posts received via a chewing or grinding action of the jaw.

The present invention generally relates to osseointegrated implants. In particular, embodiments of the present invention relate to extraosseous implants, for example, supra crestal implants, that are configured to substantially continuously cover the 3D topography of a top and a lateral surface of a bone, for example, a crestal and a lateral surface of the jaw. For example, the implants may be used on partially or completely edentulous jaws. Also, embodiments of the present invention relate to such implants made from biocompatible material of suitable porosity and elastic modulus. Specifically, embodiments of the present invention relate to improved implants suitable for implantation to bone deficient in quantity or quality, such as severely resorbed jaw bone. Further embodiments relate to a unique composite material comprising PEEK, bioglass and PMMA, and formed using triacrylate.

An approach is disclosed that involves creating an implant-supported prosthesis that is dynamically guided into position using an image-guided navigation system into position in a patient's mouth without the use of a surgical guide.

The present disclosure features adhesive compositions and methods of use thereof related to the medical, veterinary, and dental fields.

Embodiments of the disclosure relate to implantable objects and guiding devices, as well as recipient site preparation instruments, bone-implantable materials, and methods of fabrication and use thereof.

An approach is disclosed that involves creating an implant-supported prosthesis that is dynamically guided into position using an image-guided navigation system into position in a patient’s mouth without the use of a surgical guide.

An aligner assembly for facilitating an alignment of one or more teeth is disclosed. The aligner assembly includes a shell adapted to receive the one or more teeth. The aligner assembly further includes one or more engagement structures configured to be coupled to one of the one or more teeth or the shell. Each engagement structure includes a slot and adapted to engage with the shell for facilitating a reposition of the one or more teeth.

Provided is a method of manufacturing a bone grafting substitute having a hole. The method of manufacturing a bone grafting substitute having a hole includes a biodegradable polymer preparation operation of preparing biodegradable polymer; a molding material preparation operation of preparing a molding material by mixing the biodegradable polymer with a bone material; a molding material injection operation of injecting the molding material into a hole forming mold for molding a bone grafting substitute having a hole; and a bone grafting substitute having a hole molding operation of drying the molding material injected into the hole forming mold at a predetermined temperature.

A system for the amelioration of a recess (56) is disclosed, particularly of a recess in a porous, perforate material having cavities freed by the recess, said system comprising an element (2) for generating or coupling in mechanical energy, and a cylindrical collar (4, 40) having a central recess (44,45) for receiving a guide pin (8), wherein the guide pin (8), having a cannulation (35), is provided to be inserted substantially as far as the bottom of the recess (56) under positioning using a wire (52) before mechanical energy is applied, wherein the guide pin (8), in the area of the end thereof directed toward the bottom of the recess (56), is surrounded by an amelioration sleeve (7), wherein the external cylindrical jacket surface of the amelioration sleeve (7) has substantially the same external diameter as the collar (4, 40), and wherein the guide pin (8) is received movably in the central recess (44,45) such that, when mechanical energy is applied, the collar (4,40) can be moved relative to the guide pin (8) in the direction toward the bottom of the recess (8) while liquefying and laterally and/or longitudinally displacing the material of the amelioration sleeve (7).