The following invention is a device for measuring the force applied by the residual limb of an amputee to the distal region of a socket. The device has an upper surface with a “force sensor measuring region” that maintains a central location on the upper surface of the DFMD. The DFMD is affixed to the inside surface of the distal most area of the socket and maintains a permanent location of the “force sensor measuring region” of the device. Regardless of physical characteristics or changes to the socket, liner, socks, proper or improper placement of the limb into the socket, the consistent location of the “force sensor measuring region” on the DFMD provides congruent force data as it relates to the force applied by the socket to the distal area of the residual limb. The data collected by the DFMD is processed and modified by a software algorithm into meaningful data for the user and/or medical professional. Applicable uses for the data relate to the fit of the socket, limb volume management strategy, and vacuum suspension efficacy.

A leg prosthesis wherein the prosthesis shaft and the transtibial part are connected by a prosthesis shaft adapter. The prosthesis shaft adapter is constructed as a compact one-part component with a liner (sleeve as inner prosthesis shaft adapter) of the amputation stump and with a rearward extension for the prosthesis receptacle connection. The prosthesis shaft adapter is designed such that, in addition to the rearward extension of 1 cm to 10 cm, the prosthesis receptacle connection is also angled and laterally offset. Advantageously, the leg prosthesis according to the invention has a relatively low weight due to the prosthesis shaft adapter as a connecting element. The leg prosthesis operates absolutely safely and can be efficiently produced. The fabrication of a leg prosthesis with an individual biomechanical fit to the patient is significantly facilitated, which also results in fewer faulty prostheses.

A leg prosthesis wherein the prosthesis shaft and the transtibial part are connected by a prosthesis shaft adapter. The prosthesis shaft adapter is constructed as a compact one-part component with a liner (sleeve as inner prosthesis shaft adapter) of the amputation stump and with a rearward extension for the prosthesis receptacle connection. The prosthesis shaft adapter is designed such that, in addition to the rearward extension of 1 cm to 10 cm, the prosthesis receptacle connection is also angled and laterally offset. Advantageously, the leg prosthesis according to the invention has a relatively low weight due to the prosthesis shaft adapter as a connecting element. The leg prosthesis operates absolutely safely and can be efficiently produced. The fabrication of a leg prosthesis with an individual biomechanical fit to the patient is significantly facilitated, which also results in fewer faulty prostheses.

The present invention relates to an adaptor for mounting a prosthesis to a prosthetic pin that protrudes from a user's body. The adaptor comprises a male part coupled to a prosthetic pin, a female part coupled to the prosthesis and to the male part, and a locking ring for locking a rotation of the male part relative to the female part. According to the invention, the female part further comprises an at least partially resilient bush arranged in the female part that is configured to expand in a radial direction when the bush is compressed in an axial direction to lock a rotation of the male part relative to the female part.

A method and an osseointegrated prosthesis system having an osseointegrated prosthesis member are provided having a monitoring system operably coupled to the osseointegrated prosthesis member configured to quantitatively assess the osseointegration of the osseointegrated prosthesis member, a wave-generating element coupled to the osseointegrated prosthesis member and configured to output guided waves along the osseointegrated prosthesis member interrogating an interface between bone and the osseointegrated prosthesis member, and a sensing system configured to sense a condition of the interface between bone and the prosthesis.

A method and an osseointegrated prosthesis system having an osseointegrated prosthesis member are provided having a monitoring system operably coupled to the osseointegrated prosthesis member configured to quantitatively assess the osseointegration of the osseointegrated prosthesis member, a wave-generating element coupled to the osseointegrated prosthesis member and configured to output guided waves along the osseointegrated prosthesis member interrogating an interface between bone and the osseointegrated prosthesis member, and a sensing system configured to sense a condition of the interface between bone and the prosthesis.

A system and method for transferring proprioceptive and/or sensory information from a prosthesis or from a sensing system disposed at a body part having poor or no sensation, to the skin of a user wearing the prosthesis or the sensing system, includes: a device for providing electrotactile feedback in the form of an electrical stimulation pattern with coding scheme for at least one input signal; and at least one multi-pad electrode configured to be positioned on a part of the body of the user. The multi-pad electrode includes a plurality of pads configured to be selectively and discretely activated/deactivated according to the predefined stimulation pattern.

A system and method for transferring proprioceptive and/or sensory information from a prosthesis or from a sensing system disposed at a body part having poor or no sensation, to the skin of a user wearing the prosthesis or the sensing system, includes: a device for providing electrotactile feedback in the form of an electrical stimulation pattern with coding scheme for at least one input signal; and at least one multi-pad electrode configured to be positioned on a part of the body of the user. The multi-pad electrode includes a plurality of pads configured to be selectively and discretely activated/deactivated according to the predefined stimulation pattern.

The present invention provides a detection device for detecting a load and moment and capable of increasing the output by a strain gage. The detection device is provided with a characteristic sensor block. The sensor block includes a base having an axis extending in the direction of a load to be detected, a front side wall raised from the base at a position offset from the axis of the base, a rear side wall raised from the base at a position offset from the axis of the base in the direction opposite the front side wall, and an upper wall for connecting the upper end of the front side wall and the upper end of the rear side wall. The sensor block supports each strain gauge on the upper surface of the upper wall. The upper wall includes a center portion located at the center between the front side wall and the rear side wall, a first portion located between the center portion and the front side wall, and a second portion located between the center portion and the rear side wall. The first portion and the second portion, which support the strain gauges, have a smaller thickness than the center portion and are relatively easily deformed or strained.

The present invention provides a detection device for detecting a load and moment and capable of increasing the output by a strain gage. The detection device is provided with a characteristic sensor block. The sensor block includes a base having an axis extending in the direction of a load to be detected, a front side wall raised from the base at a position offset from the axis of the base, a rear side wall raised from the base at a position offset from the axis of the base in the direction opposite the front side wall, and an upper wall for connecting the upper end of the front side wall and the upper end of the rear side wall. The sensor block supports each strain gauge on the upper surface of the upper wall. The upper wall includes a center portion located at the center between the front side wall and the rear side wall, a first portion located between the center portion and the front side wall, and a second portion located between the center portion and the rear side wall. The first portion and the second portion, which support the strain gauges, have a smaller thickness than the center portion and are relatively easily deformed or strained.