The present invention is directed generally to (1) an articulating junction, and articulation method thereof, wherein articulation is facilitated by a plurality of magnetic particles; (2) an articulating junction, and articulation method thereof, wherein the stability and fluidity of the junction is based, at least in part, on the magnetic field(s) of the plurality of magnetic particles; and (3) reducing the resistance to articulation and/or increasing the structural integrity and support, of the articulating junction, via electro-magnetism. Further, the present invention is directed generally to the synergistic combination of magnetic particles and preferred bio-implant-materials and additive-manufacturing methods along with Baker correlation codes. Further, the present invention is directed to an artificial joint for implantation into a living body and methods for constructing such an artificial joint.

An example method for producing a prosthetic device for a patient includes obtaining imaging data corresponding to a body part of a patient, generating an object model corresponding to the body part based on the imaging data, generating a prosthesis model based on the object model, generating a set of instructions based on the prosthesis model, and executing the set of instructions using a three-dimensional printer, where the set of instructions, when executed by the three-dimensional printer, cause the three-dimensional printer to produce the prosthetic device for the patient.

Prostheses include a terminal device, a back-lock mechanism, a wrist, a limb-socket, and a harness system. The terminal device can be a five-fingered mechanical hand that provides a releasable adaptive grasp, and has independently flexible fingers. The limb socket can be 3D printed using a molded model of a remnant limb. The harness strap can encircle an unaffected limb and is coupled to the terminal device with a cable so that a user can control the terminal device. The harness system can include a 3D printed harness ring that couples to the cable.

Prosthesis devices can include sockets having adjustable features. In one example, a socket includes one or more panels that can move outwardly or inwardly relative to a receptacle portion of the socket. The panels can be moved by tightening a tensioning line.

A prosthetic foot device (1) having a longitudinal direction (L) and a transverse direction (T) and comprising a base spring blade (2), an ankle spring blade (3) being made from a composite material comprising glass fibres and a heel spring blade (4), the base spring blade (2) and the ankle spring blade (3) being connected in a forefoot region (5) of the prosthetic foot device (1), the base spring blade (2) and the heel spring blade (4) being connected in a heel region (7) of the prosthetic foot device and the ankle spring blade (3) and the heel spring blade (4) being connected in an ankle region (9) of the prosthetic foot device.

A compliant prosthetic foot is designed and fabricated by combining a compliant mechanism optimization technique with a calculation of low leg trajectory error under a reference loading condition. The compliant mechanism optimization technique includes a set of determinants for the compliant prosthetic foot. An optimized set of determinants of the compliant prosthetic foot is formed that minimizes the lower leg trajectory error relative to a target kinematic data set. The compliant prosthetic foot is then fabricated in conformance with the optimized set of determinants.

A method utilizing digital scanning, additive manufacturing, and electronic embedded garments for advanced fitment of prosthetic devices.

A fairing can be attached to a prosthetic limb or over a brace to alter the appearance of the prosthetic limb or brace. The outer surface of the prosthetic limb can be a mirror image of an intact limb and the outer surface of the brace can have an outer surface that corresponds to an injured limb. Because the fairing fits closely around the prosthetic limb or brace, the interior surface of the fairing has a surface that corresponds to a mirror image of an intact limb or an outer surface of an injured limb.

The invention relates to a socket system for a prosthesis. The socket system including a prosthesis socket which has a proximal opening for receiving a residual limb and a distal end and which is made, at least partially, of a first fiber-reinforced plastic. The socket system also includes an adapter element which is arranged on the distal end of the prosthesis socket and is designed in such a manner that a distal prosthesis element can be secured to the adapter element. The adapter element includes a base body which is made, at least partially, of a second fiber-reinforced plastic.

A breast prosthesis device and method for making same are disclosed. The prosthesis has an inner wall mesh having a first density. The inner wall mesh is configured to align with a chest wall of the user. The prosthesis has an outer wall mesh having a second density. The outer wall mesh configured to have an ideal shape for the user. The prosthesis may also have a band with a density greater or equal to the inner and outer wall meshes. The prosthesis has a central portion disposed in between the inner and outer wall meshes. The prosthesis can be generated using 3D scans of the user manipulated such that the resulting structure mimics human tissue.