An orthopedic implant has an implant body defining a longitudinal axis extending in a direction of implantation of the orthopedic implant, the implant body having a first end portion and a second end portion. A porous structure extends circumferentially around the implant body and has a first circumferentially-extending zone exhibiting a first coefficient of friction with bone tissue and a second circumferentially-extending zone exhibiting a second coefficient of friction with bone tissue, wherein the second coefficient of friction is greater than the first coefficient of friction. The first circumferentially-extending zone of the porous structure is offset from the second circumferentially-extending zone along the longitudinal axis such that during implantation of the orthopedic implant, the first circumferentially-extending zone of the porous structure contacts bone before the second circumferentially-extending zone of the porous structure.

A surgical navigation system comprising a signal receiver communicatively coupled to a primary processor, the primary processor programmed to utilize a sequential Monte Carlo algorithm to calculate changes in three dimensional position of an inertial measurement unit mounted to a surgical tool, the processor communicatively coupled to a first memory storing tool data unique to each of a plurality of surgical tools, and a second memory storing a model data sufficient to construct a three dimensional model of an anatomical feature, the primary processor communicatively coupled to a display providing visual feedback regarding the three dimensional position of the surgical tool with respect to the anatomical feature.

A mould adapted to be introduced into a joint of a human patient for resurfacing at least one carrying contacting surface of said joint is provided. The mould is adapted to receive material for resurfacing at least one carrying contacting surface of said joint. The mould is further adapted to be resorbed by the human body or melt after having served its purpose.

The present invention relates to a lattice support structure for one or more degenerated portions of subchondral bone of a bone epiphysis part of a human or animal joint, and to a related kit of parts and to a template assembly for the assembly thereof.

The lattice structure comprises at least one rod-shaped and substantially rectilinear rigid primary element configured to be housed within said bone epiphysis extending at least partially through said degenerated portion of subchondral bone along a respective primary extension direction; and a plurality of thread-like substantially rectilinear secondary elements configured to be housed within said bone epiphysis extending at least partially through said degenerated portion of subchondral bone along respective secondary extension directions, comprising first secondary elements configured to extend along respective first secondary extension directions and second secondary elements configured to extend along respective second secondary extension directions (Yd, Ye, Yf), the first and second secondary extension directions being oblique to one another, wherein the at least one primary element has a first transversal dimension greater than a second transversal dimension of said secondary elements.

The at least one primary element and the secondary elements are further configured to reach and cross at least partially, at respective opposite ends, cortical bone portions of said bone epiphysis.

A total elbow replacement prosthesis (100) comprising: a radioulnar component (20) having an ulnar bearing surface (22) and an anconeal process bearing surface (24), a humeral component (40) having a trochlear bearing surface (42), the trochlear bearing surface being configured for bearing against the ulnar bearing surface, the humeral component further comprising an olecranon aperture boundary bearing surface (50), the anconeal process bearing surface being configured for bearing against the olecranon aperture boundary bearing surface.

An implantable orthopedic wedge can include a main body having a base portion and an apical portion, the apical portion including a first end. The main body can have a thickness that tapers along a perimeter of the main body from a first thickness at the base portion to a second thickness at the apical portion. The implantable orthopedic wedge can also include a fixation member coupled to the main body and configured to receive one or more anchoring elements to anchor the wedge to an implantation site.

A human or animal joint is treated by introduction of a device between the suitably prepared articulating surfaces of the joint, and the device is anchored in both these articular surfaces with a material having thermoplastic properties. For allowing at least limited articulation of the joint after implantation, the device includes two articulating portions, wherein one of the articulating portions is anchored in each articulating surfaces of the joint. On implantation a proximal face of the device is contacted with a vibrating tool and the vibration is transmitted through parts of the device to locations in which the material having thermoplastic properties is near the bone tissue of the articulating surfaces of the joint and in which liquefaction is desired. The liquefied material penetrates the bone tissue and, on re-solidification forms a positive fit connection between the device and the bone tissue.

An implant for repairing a segmental defect in a subject's bone at a segmental defect site, the implant comprising a scaffold for implantation at the segmental defect site and the implant optionally comprising: a plate for internal fixation, the plate being attachable to or integral with the scaffold, and the plate having means for securing it to bone outside of the segmental defect site; a hollow cavity within the scaffold; a plurality of longitudinal channels within the scaffold; and or a membrane received around the scaffold.

A cutting guide for guiding a cut in a radius, the radius being adjacent to an ulna, the cutting guide comprising: a cut guiding portion, an opposed ulnar mounting portion and a linking portion extending therebetween; the cutting guide being delimited by a cutting guide peripheral surface defining a bone facing portion, the bone facing portion being contoured to match the shape of the radius and ulna.

A veterinary hip resurfacing prosthetic system includes a femoral cap and an acetabular cup. The cup shell has a thickness of less than 2 mm and a liner in the shell has a thickness of less than 2.5 mm in order to accommodate a larger femoral cap. Further included are features for preventing rotation of the liner relative to the shell, for releasably locking the liner in the shell, and for accessing the liner to remove it from the shell.