Disclosed are femoral stem for hip implants, and methods of design and manufacture thereof. A femoral stem for a hip implant, comprising a femoral neck extending from a proximal end of the femoral stem towards a distal end of the femoral stem; an upper section connected to and extending from the femoral neck towards the distal end of the femoral stem, wherein the upper section comprises at least one proximal-distal solid rib flanked by an open lattice; and a lower section connected to and extending from the upper section to the distal end of the femoral stem, wherein the lower section comprises a closed lattice enclosed in a solid skin. Such femoral stems for hip implants are customized and manufactured using 3D printing technologies and provide a lightweight alternative to conventional him implants.

The present invention provides a fused femoral stem system, including a curved short handle, a fixing mechanism and a femoral head prosthesis, one end of the curved short handle is provided with a conical connector, the conical connector is cooperatively connected with a conical connecting hole of the femoral head prosthesis, the other end of the curved short handle is inserted from the osteotomy surface of the femoral neck and stretches to the position of a medullary cavity below a small trochanter, and the curved short handle is connected and fixed with a large trochanter through the fixing mechanism. The present invention has the beneficial effects that, after the growing-in osseointegration with the sclerotin surrounding the proximal bone bed of the host after the surgery of the whole system, the mechanical influence on the retained femoral neck and the sclerotin in the vicinity of the large and small trochanters is substantially similar to the biomechanical state prior to the surgery.

A method for manufacturing an implant includes pre-selecting a designed porous microstructure having a lattice composed of cells, including selecting one or more predetermined cell topologies, selecting a predetermined porosity, cell strut thickness and packing factor of the lattice, and selecting an arrangement of the cells within the lattice to have a periodic and/or aperiodic arrangement. Additive manufacturing is used to form the designed porous lattice microstructure in at least a region of at least an external surface of the implant.

An implantable prosthesis including a stem and a stem head. The stem extends along a longitudinal axis from a proximal end portion to a distal end portion of the stem. The stem head is coupled to the proximal end portion of the stem. The stem head is configured to be coupled to a joint component. The stem head includes a side surface and a side surface cleat. The side surface cleat defines a first side surface groove and a second side surface groove. The side surface cleat extends between the first side surface and the second side surface.

An implant for a hip can include a lateral augment adapted to be coupled to a lateral side of a femoral body implant. The lateral augment can include a body portion having a first surface, a second surface opposite the first surface, and a protrusion extending from the second surface. The protrusion can have a shape adapted to mate with a complementary shaped recess formed in the lateral side of the femoral body implant. An aperture can be positioned in the body portion and extend through the protrusion. A fastener can be received through the aperture and adapted to be threadably secured to the lateral bore. The fastener can be configured to have a length sufficient to pass through a portion of a greater trochanter for securing the portion of the greater trochanter and the lateral augment to the femoral body implant.

A bufferable femoral implant includes a metallic main body, and an elastomer member integrally formed or connected to a lower portion of the metallic main body, whereby when an external force acts upon the femoral implant as implanted in a patient's femur, the elastomer member as packed within the medullary cavity in the femur will bufferably dampen such an external force for safely protecting the patient's femur, the femoral implant and the related hip bones.

A hip implant has a neck body that connects to a bone fixation body. The bone fixation body has a porous structure with an elongated shape. An internal cavity is formed in the bone fixation body and includes a substance to stimulate bone growth.

The invention relates to a prosthesis for implantation into a long bone during joint arthroplasty, particularly Total Shoulder Arthoplasty and Total Hip Arthroplasty, and a method for use of the implant.

A device for reinforcing a femoral neck bone, the femoral neck bone including a cortical bone region and a cancellous bone region, the device including a support structure having an outer surface and including a portion having one or more bores, the one or more bores adapted to allow filler material to be released therefrom to enter directly into the cancellous bone.

A system for assisting in a surgical process, comprising: (a) a surgical device taken from a group consisting of a surgical tool and a surgical implant; (b) a positional sensor carried by the surgical device, the positional sensor including a wireless transmitter and associated circuitry for transmitting sensor data from the transmitter; and (c) a computer system including a wireless receiver and signal conditioning circuitry and hardware for converting sensor data received by the wireless receiver into at least one of (i) audio feedback of positional information for the surgical device and (ii) visual feedback of positional information for the surgical device.