Various examples are provided for modular prosthetic devices and their use. In one example, a device includes a chassis assembly including a joint portion; and an interchangeable module that can be removably attached to the chassis assembly. The interchangeable modules can be configured for use in a wide variety of applications. The interchangeable modules can be quickly exchanged for different activities.

A support structure, a prosthesis component, and a method for producing a prosthesis component.

Disclosed herein are a method and system for producing a digital model of a customised device, comprising the steps of: importing a first digital file of a base part; importing a second digital file of a target shape; determining a warping interpolation function based on source point positions associated with the base part and target point positions associated with the target shape; and applying the warping interpolation function to the points of said base part to generate a model of said customised device.

An antimicrobial prosthetic liner having an exterior fabric layer and an inner layer comprising a thermoplastic and further incorporating evenly distributed nanoparticles of certain metal oxide nanoparticles in an amount ranging from 2%-6% weight per weight and ranging in size from between 5 nanometers and 100 nanometers in diameter, most preferably 20 nanometers in diameter. Preferably, the metal oxide nanoparticles used are titanium dioxide and zinc oxide. Copper oxide, magnesium oxide, aluminum hydroxide as well as metal nanoparticles such as gold nanoparticles and silver nanoparticles may also be used to provide antimicrobial effects.

An antimicrobial prosthetic liner having an exterior fabric layer and an inner layer comprising a thermoplastic and further incorporating evenly distributed nanoparticles of certain metal oxide nanoparticles in an amount ranging from 2%-6% weight per weight and ranging in size from between 5 nanometers and 100 nanometers in diameter, most preferably 20 nanometers in diameter. Preferably, the metal oxide nanoparticles used are titanium dioxide and zinc oxide. Copper oxide, magnesium oxide, aluminum hydroxide as well as metal nanoparticles such as gold nanoparticles and silver nanoparticles may also be used to provide antimicrobial effects.

A suspended sleeve assembly includes a suspension stand and a compression sleeve. An upper portion of the compression sleeve is attached onto the suspension stand, but a lower portion of the compression sleeve is unattached from the suspension stand. The suspended sleeve assembly can also include a support stand. The suspended sleeve assembly can be used to shape a prosthetic socket. The compression sleeve applies a circumferential pressure onto the prosthetic socket as the prosthetic socket is being inserted into the compression sleeve as a patient steps into the compression sleeve and applies at least a portion of body weight to the compression sleeve. The prosthetic socket can be heated and shaped by hand, so that it fits the residual limb of the patient. The suspended sleeve assembly can also be used to shape other prosthetic components, such as a negative plaster cast.

A system and a method for creating prosthetics using a prosthetic machine are disclosed. The method includes creating a three dimensional (3D) shape of a prosthetic using a software. Successively, the 3D shape is sent for printing based at least on an availability of a printer. The printing is achieved by taking the 3D shape and slicing into very thin horizontal slices and thereafter placing a slice upon a slice for the 3D shape. Further, granular polycarbonate material is placed in a cartridge at the top of a compression head. Further, granules are fed through a four stage heating and compression process. Further, a heated plastic is pressurized and forced through an extruder to extrude in a 1 mm×4 mm ribbon. Thereafter, a printed object is formed on a base plate through motion that is controlled by a plurality of linear axes and a rotary axis.

A ventilated prosthetic socket includes a rigid, structural and load-bearing socket body forming an inner volume adapted to receive a residual limb, and a wall thickness extending from an inner wall surface bordering the inner volume to an outer wall surface. The socket body defines an opening extending through the wall thickness. At least one vent element communicates the inner wall surface to the outer wall surface and extending therebetween in the opening along the socket body to thereby permit a transfer of air from the inner volume to outside of the socket through the opening. The at least one vent element is separately formed from the socket body and discretely insertable into the opening and secured against the inner surface and the outer wall surface. A method and kit are provided to adapt the socket in a ventilated form.

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 system for electronically capturing a subject's anatomy. Software programming directs the user to position the camera to recognize the anatomy. It uses anatomical features of the recognized subject's anatomy, patient data entered by the user and anthropometric data to estimate the optimal position of virtual markers. Furthermore, it places the virtual markers on an image presented to the user on the display screen at the estimated optimal position, while utilizing an auto-zoom and the virtual markers to zoom in to provide proper framing. The auto-zoom is utilized while maintaining a substantially fixed camera distance from the subject. The programming provides feedback based on the anatomical features for directing the user to move the camera appropriately relative to the virtual markers, thereby resulting in an optimized view of the anatomical information. The end-user software program captures the optimized view of the anatomical information via the camera to provide output data.