Prosthetic component provided with a stem, adapted to be implanted in use at a bone of a patient, such as for example a tibial and/or femoral component of a knee prosthesis or a femoral component of a hip prosthesis or a humeral component of a shoulder prosthesis, or a component of an elbow prosthesis, including a device adapted to externally cover and/or to house at its interior at least the stem of the prosthetic component, wherein the device is in use placed between the prosthetic component and the bone of the patient, suitable to stably constrain in use the prosthetic component to the bone of the patient and to prevent the direct contact between prosthetic component and bone of the patient.

Prosthetic component provided with a stem, adapted to be implanted in use at a bone of a patient, such as for example a tibial and/or femoral component of a knee prosthesis or a femoral component of a hip prosthesis or a humeral component of a shoulder prosthesis, or a component of an elbow prosthesis, including a device adapted to externally cover and/or to house at its interior at least the stem of the prosthetic component, wherein the device is in use placed between the prosthetic component and the bone of the patient, suitable to stably constrain in use the prosthetic component to the bone of the patient and to prevent the direct contact between prosthetic component and bone of the patient.

An orthopaedic implant includes an implant body comprising a biocompatible material and configured to be implanted at an anatomical location, the implant body defining a surface; and a porous material at least one of attached to and integral with the surface of the implant body, the porous material having a plurality of grooves formed therein.

A neck trial (170) is disclosed. The neck trial has a body (182) and a neck (186). The body has an exterior surface. The neck extends away from the body along a neck axis (190). At least one first line (194) is provided on the exterior surface, which extends in a first direction parallel to an inferior-superior axis of a patient when in use. At least one second line (196) is provided on the exterior surface, which extends in a second direction parallel to a medial-lateral axis of the patient in use. The number of first lines, or the position of the first line or lines relative to the second line or lines, is indicative of an amount of offset in the medial-lateral direction caused by the neck trial. The number of second lines, or the position of the second line or lines relative to the first line or lines, is indicative of an amount of leg-length in the inferior-superior direction caused by the neck trial. A kit of parts, a trial assembly and a method of trialling a joint of a patient are also disclosed.

A femoral stem for use in hip replacement surgery, specifically hip replacement surgery in dogs and similar animals but also inclusive to implants used in humans. More particularly, the invention is directed to a femoral stem that includes a lateral bolt or post that protrudes through the cortex or wall of bone opposite the neck of the femoral stem. The lateral bolt or post reduces the occurrence of subsidence in implanted femoral stems. The lateral bolt or post provides an anchor point on the cortex or wall of bone as opposed to relying solely on the compression of the femoral stem against the wall of the bony canal of the femur being implanted.

The present invention is an internal osseointegrated transfemoral amputee implant device and related methods. The device is designed to restore the enclosed nature of the bone marrow system which is disrupted by amputation, plus provide a pressure tolerant (weight-bearing) surface and mechanical anchoring for the iliotibial band.

This invention relates to orthopaedic implants having one or more regions of three dimensional lattice that substantially replicate the trabecular orientation within a healthy bone from the same anatomical location as the implant. A method for the manufacture of such orthopaedic implants is also disclosed using additive manufacturing techniques and patient-specific anatomical information.

A joint prosthesis includes first and second articulated corresponding joint components implantable within a body of a patient, wherein the corresponding joint components have corresponding surfaces that are relatively displaceable with respect to each other over a predefined functional range of motion of the corresponding joint components. The corresponding joint components each comprise one or more magnetic elements creating gradient magnetic fields having relatively strongest and weakest field areas over different portions of each of the corresponding surfaces, wherein the gradient magnetic fields are strongest in attraction at positions of the corresponding surfaces which align when the corresponding surfaces are at a boundary of the predefined functional range of motion, and deter joint dislocation by deterring relative movement of the corresponding surfaces beyond the boundary.

A joint prosthesis includes first and second articulated corresponding joint components implantable within a body of a patient, wherein the corresponding joint components have corresponding surfaces that are relatively displaceable with respect to each other over a predefined functional range of motion of the corresponding joint components. The corresponding joint components each comprise one or more magnetic elements creating gradient magnetic fields having relatively strongest and weakest field areas over different portions of each of the corresponding surfaces, wherein the gradient magnetic fields are strongest in attraction at positions of the corresponding surfaces which align when the corresponding surfaces are at a boundary of the predefined functional range of motion, and deter joint dislocation by deterring relative movement of the corresponding surfaces beyond the boundary.

An implant or endoprosthesis suitable to be implanted in human or animal tissue includes two (or more than two) parts to be joined in situ. Each one of the parts includes a joining location, the two joining locations facing each other when the device parts are positioned for being joined together, wherein one of the joining locations includes a material which is liquefiable by mechanical vibration and the other one of the joining locations includes a material which is not liquefiable by mechanical vibration and a structure (e.g. undercut cavities or protrusions) suitable for forming a positive fit connection with the liquefiable material. The joining process is effected by pressing the two device parts against each other and by applying ultrasonic vibration to one of the device parts when the two parts are positioned relative to each other such that the two joining locations are in contact with each other.