A method and device for digital measuring and ordering a custom orthopedic device includes an interactive method intended to assist clinicians select, measure and submit precise specifications for patients requiring custom orthopedic devices. The method includes a plurality of menus permitting the clinician to input specifications and submit orders electronically with the specifications and other data packaged together. The method and device include visualization indications to appropriately ensure image capture of a limb from various angles, including posterior, anterior, lateral and medial angles.

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 relates to a method for producing an orthopedic device, particularly a prosthesis liner, characterized in that the orthopedic device is produced at least partially by means of an additive manufacturing process from at least one production material that is introduced into a support material in a flowable state and then hardens.

A selectively actuated textile includes one or more pieces of fabric having one or more circumferentially constrained channels and one or more hollow elastic tubes located within the circumferentially constrained channels and configured to receive a working fluid. Selectively providing or removing working fluid from the hollow elastic tubes provides for selective actuation of the textile.

A system for controlling a body part includes a number of sensing devices that sense signals from a hemisphere of a brain. A signal translating unit translates the signals into a command signal for controlling the body part, which is on a same side of the body as the hemisphere of the brain. A prosthetic device receives the command signal from the signal translating unit and manipulates the body part in response to the command signal.

A system for controlling a body part includes a number of sensing devices that sense signals from a hemisphere of a brain. A signal translating unit translates the signals into a command signal for controlling the body part, which is on a same side of the body as the hemisphere of the brain. A prosthetic device receives the command signal from the signal translating unit and manipulates the body part in response to the command signal.

A prosthetic or orthotic device includes a body configured to support at least a portion of a human limb of a user wearing the prosthetic or orthotic device. The device can also include a shock absorption member coupled to the body. The shock absorption member includes one or more magnetorheological elastomer (MRE) springs disposed between a first portion of the body and a second portion of the body. The one or more MRE springs are selectively actuatable to vary a stiffness of the shock absorption member via the application of a magnetic flux, thereby adjusting a stiffness of the body of the prosthetic or orthotic device to a level corresponding to an activity level of the user.

A prosthetic device includes a prosthesis wall, at least one display carried by the prosthesis wall in spaced-apart relationship to the at least one display and interfacing with the at least one display, the control module adapted to present at least one image on the at least one display.

The system includes an instrument for determining the anatomical, biomechanical, and physiological properties of a body segment that includes one or more force sensitive probes is provided. A human operator actuates one or more force sensitive probes, wherein the force sensitive probes are positioned at the surface of the body segment. The operator pushes on the force sensitive probes with varying force applied on the body segment to measure tissue deflection forces. The instrument may include one or more of gyroscopes, accelerometers, and magnetometers capable of measuring changes in tissue deflection caused by the force sensitive probes relative to a grounded reference frame in 3-D space, wherein the tissue deflection force data and the change in tissue deflection data are used to compute segment tissue viscoelastic properties. The instrument may also be untethered or wireless.