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 present invention relates to a method for manufacturing or planning the manufacturing of a prosthetic shaft, an inner or outer shaft and/or of an extension of the prosthetic shaft, wherein the prosthetic shaft is provided for receiving a limb stump of a patient P. The present invention further relates to prosthetic shaft and a kit. Furthermore, a computer system, a digital storage medium, a computer program product and a computer program are proposed.

Disclosed are systems, methods and computer-readable medium for developing a custom design for a prosthetic for a residual limb comprising: measuring, using a scanning apparatus, a usable measurement of the residual limb; and creating, using a computing device, a design for a prosthetic for at least a portion of a missing portion of the residual limb, wherein the prosthetic is proportionally sized according to a correlation between the usable measurement and normal anthropometric measurements.

A system and method for producing a customized prosthetic socket based on a digital representation of a residual limb that is used to form a digital model of a prosthetic socket. The digital model is customized to alter its internal structure to produce differing areas of flexibility and support while maintaining the overall geometry of the model and without having to use different materials. The digital model is converted for use with a three-dimensional printing or manufacturing device and then used to print the customized socket.

A method, apparatus, media and signals for producing a representation of a mold for forming an appliance for a living body is disclosed. The method involves identifying points representing a line corresponding to an intended edge of the appliance on a surface of the mold, the surface being defined by an input plurality of points representing a general shape of the mold. The method also involves identifying regions extending along the surface on opposite sides of the line, adjusting at least one coordinate of at least one of the input plurality of points that falls within at least one of the regions to alter the shape of the surface in the at least one region to produce a modified surface representation, and storing the modified surface representation in a computer memory to produce a modified representation of the mold.

A system for sizing and fitting an individual for apparel, accessories, or prosthetics includes at least one energy emitter configured to emit energy onto a field-of-view that contains an individual, and at least one energy sensor configured to capture reflected energy from within the field-of-view. A spatial measurement module calculates spatial measurements of a surface portion of the body of the individual when the individual is either stationary or moving about in real-time, based on data from the energy sensor.

The invention is a 3D printed prosthetic socket for a residual limb consisting of a 3D printed shell. The 3D printed prosthetic socket comprises a distal end adapted for linking the interconnecting adapter of the socket and a proximal end with an opening adapted for inserting the limb. The 3D printed shell comprises a first housing of the socket comprising an inner wall and an outer wall, wherein the first housing of the socket comprises a rigid region having, in the direction perpendicular to the inner wall, the rigidity of the rigid region and an elastic region having, in the direction perpendicular to the inner wall the rigidity of the elastic region. The rigidity of the elastic region is smaller than the rigidity of the rigid region, wherein the elastic region comprises a set of shaped openings and is adapted for softening the contact of the residual lower limb with the prosthetic socket, wherein the 3D printed shell is made of a single 3D printed part.

The invention relates to a method for producing a prosthetic liner for insertion into a prosthetic socket, which comprises a receptacle having a distal end and a proximal edge for a residual limb and the prosthetic liner. Said The method comprises determining a sealing lip contour on the outer face of the prosthetic liner which corresponds to a height contour of the proximal edge of the prosthetic socket, or on the basis of available, known anatomic characteristics of the residual limb and arranging a sealing lipon the outer face of the prosthetic liner along the determined sealing lip contour.

The invention relates to a method for creating a 3D scan of a body part, the method comprising the following steps: a. Molding a contact element to the body part, b. Capturing a first partial scan of the body part, c. Removing the body part from the contact element, d. Capturing a second partial scan of the contact element, and e. Creating the 3D scan at least also from the first partial scan and the second partial scan.