The invention provides a nonmetal implant screw locking structure, which has the advantages of simple structure, novel design, simple production and processing, and convenient clinical operation. In addition, the structure of the invention can be used for orthopedic nonmetal implants such as the bone injury repair plate, spinal fusion cage, spinal fixation plate, posterior cervical single trapdoor plate, posterior cervical plate, lumbar anterior plate and lumbosacral plate, bringing good economic and social benefits gradually.

A fixation device includes a first anchor portion configured to join to a first bone portion, a second anchor portion configured to join to a second bone portion, and an intermediate component that extends between the first anchor portion and the second anchor portion. The intermediate component is configured to expand, contract, and angulate enabling constrained movement of the second bone portion with respect to the first bone portion. The second anchor portion has a larger configuration relative to the first anchor portion, thereby preventing the second bone portion from depressing below the first bone portion.

A bone plate (1) for positioning along a medial or lateral portion of a clavicle including an upper surface (2) which, in an operative position, faces away from the clavicle, a lower surface (3) which, in the operative position, faces toward the clavicle, a non-linear central longitudinal axis (4), a middle portion (5) of the length L.sub.M, a left terminal portion (6) of the length L.sub.L extending from the left end of the middle portion having a plurality of circular screw holes (8) for receiving bone screws, and a right terminal portion (7) of the length L.sub.R extending from the right end of the middle portion having a plurality of circular screw holes (9) for receiving bone screws. The total length L of the bone plate corresponds to L=L.sub.M+L.sub.L+L.sub.R, and at least one of the circular screw holes is a variable angle screw hole.

A femur fixation system includes an intramedullary nail that includes a first bending stiffness and a bone plate that includes a second bending stiffness and a second torsional stiffness. In the femur fixation system either at least one of the second torsional stiffness compensates for the first torsional stiffness and the first torsional stiffness is insufficient to enable the intramedullary nail to stabilize the bone fracture independently of the bone plate or the first bending stiffness compensates for the second bending stiffness and the second bending stiffness is insufficient to enable the bone plate to stabilize the bone fracture independently of the intramedullary nail.

An implant for the stabilization of bones or vertebrae is provided, the implant being a solid body including a longitudinal axis that defines a longitudinal direction and including a flexible section that has a surface and has a length in the longitudinal direction, the flexible section including at least one cavity located near the surface and having a width in the longitudinal direction that is smaller than the length of the flexible section, the at least one cavity being connected to the surface through at least one slit, and a width of the slit in the longitudinal direction being smaller than the width of the cavity.

A bone plate and method for use thereof affords use of at least two surgical approaches to attach the bone plate to a fractured bone to facilitate reduction and repair thereof. The bone plate includes two domains extending in different directions from a transition zone. The directions in which each of the two domains extend are generally opposite, and the transition zone is configured to afford portions of the two domains to be substantially disposed in planes that are transverse to one another.

A plate for fracture fixation is provided including a plurality of individually adjustable heads and various features to achieve: a.) superior fixation of the plate to osteoporotic diaphyseal bone; b.) improved visualization of the fracture line; c.) intraoperative adjustability to achieve better contact of the plate and the bone; d.) reduced risk of post-surgery tendon rupture; d.) improved fixation of small volar marginal fragments and, e.) improved targeting and fixing of particular fractured bone fragments.

Modular bone reinforcement systems, bone plates, assembled bone reinforcements, and methods of reinforcing a bone are described. A modular bone reinforcement system includes a plurality of bone plates, each of which has a series of tabs disposed along at least one edge of the bone plate for forming a snap-fit attachment to a mating series of tabs of another bone plate of the plurality of bone plates to form an assembled bone reinforcement. A first bone plate of the plurality of bone plates has a first shape and a second bone plate of the plurality of bone plates has a second shape that is different from the first shape. The modular bone reinforcement system can include additional components, such one or more fixation devices, reduction devices, navigation aids, or other components.

Devices, systems, and methods of bone stabilization. The bone stabilization system includes a variety of plates, including a tine plate. The tine plate may include an elongate body and first and second ears extending from the elongate body, each of the first and second ears defining a screw hole therethrough, and a first tine extending from the first ear and a second tine extending from the second ear, the first and second tines each terminating at a sharp point.

Systems and methods are described for treating distal radius fractures using a plating system. In an aspect, a distal radius plating system includes a volar plate body for interfacing with a volar side of a distal portion of a radius bone. The volar plate body has a volar head portion extending from the volar plate body and terminating at a distal edge, the volar head portion including a first set of apertures to receive fixation fasteners therethrough to fix to the radius bone. The distal radius plating system also includes a radial longitudinal portion extending from a radial edge of the volar plate body to interface with the radial styloid of the radius bone while the volar plate body is positioned on the volar side of the distal portion of the radius bone.