A prosthesis that can be actuated by external force includes a prosthesis shaft and an exoprosthesis with at least one prosthesis motor that can be activated by a prosthesis control device and a joint. The prosthesis control device includes a housing, a microcontroller and display device, so that a gripping process can be replicated by the prosthesis motor controllable by the prosthesis control device and parameters of the gripping process are displayed on a display, in which case recording and evaluation of the electromyography signals are dispensed with. The display displays the chosen parameters of an imminent gripping process and the prosthesis control device includes an input device by which a desired gripping force and/or gripping time can be actively set on the microcontroller before performance of the gripping process by a prosthesis wearer directly on the prosthesis control device and can be readjusted during the gripping process.

The breastfeeding device present in the invention, simulates natural breastfeeding experience and delivers fluid, milk or infant formula to the nursing infant in a contactless or latch free manner than any prior art in this field. This device integrates physical sensors to the breastfeeding device and includes a neck strap, refillable housing chamber that contains fluid, a tubing that connects the housing chamber to a prosthetic nipple via a sealing attachment and a prosthetic nipple for infant latching to nurse. The invention is a notable step forward in creating an effective, safe and contactless nursing which mitigates and prevents bruised, sore nipples or engorged breasts.

A method for controlling the standing-phase damping of an artificial knee joint comprising an upper part and a lower part which are secured together in a pivotal manner about a pivot axis, a resistance unit which is arranged between the upper part and the lower part and has an adjustment device via which the damping resistance can be modified, and a control unit which is coupled to the adjustment device and which is connected to at least one sensor. The adjustment is carried out on the basis of sensor data, and the knee angle is detected by the at least one sensor during the standing-phase inflexion up to the terminal standing phase. The flexion damping is increased to a level above an initial flexion damping in order to prevent a further inflexion upon reaching a specified maximum knee angle.

Systems and methods for manual gesture recognition to control prosthetic devices. Low encumbrance systems utilizing glove-based recognition to control prosthetic devices. Prosthetic control systems and methods are also provided utilizing elements for application on the user's fingernails.

Prosthetic and/or orthotic devices (PODS), control systems for PODS and methods for controlling PODS are provided. As part of the control system, an inference layer collects data regarding a vertical and horizontal displacement of the POD, as well as an angle of the POD with respect to gravity during a gait cycle of a user of the POD. A processor analyzes the data collected to determine a locomotion activity of the user and selects one or more control parameters based on the locomotion activity. The inference layer may be situated between a reactive layer control module and a learning layer control module of the control system architecture.

A supply system for at least one orthopedic technology component, which has at least one electronic and/or electrical device and has a supply connection and/or a radio device for receiving data and/or electrical energy. The supply system also includes a holder for the orthopedic technology component, which has a supply device, and which is compatible with the supply connection and/or the radio device, for supplying the orthopedic technology component with data and/or energy. The invention further relates to a system consisting of a supply system and an orthopedic technology device, and to a method for supplying the system with data and/or energy.

A prosthetic arm apparatus including a plurality of segments that provide a user of the prosthetic arm apparatus with substantially the same movement capability and function as a human arm. The segments are connectable to one another and connectable to a prosthetic support apparatus that may be adorned by the user. A prosthetic limb segment includes a housing having an input interface and an output interface, the output interface and the input interface being moveable with respect to one another, a motorized drive disposed within the housing, the motorized drive effecting movement of at least one of the output interface or the input interface, and a controller disposed within the housing for controlling actuation of the motorized drive. The controller may be configured to communicate with at least a second motorized drive of at least a second prosthetic limb segment to control actuation thereof.

A powered prosthetic thigh can have a proximal portion configured to couple to a prosthetic hip socket and can have a distal portion attached to the proximal portion. The distal portion can have a distal connector configured to couple to a prosthetic knee. The powered prosthetic thigh can also have a computer controlled actuator configured to rotate the prosthetic thigh relative to the prosthetic hip socket.

A method for producing an orthopedic device, wherein the method comprises: providing a main body of the orthopedic device that comprises at least one volume that can be filled with a fluid, at least one supply line to this volume, and a flexible and/or elastic material in at least some sections of the main body in which there is no volume that can be filled with a fluid, arranging the main body on a body part of a patient, at least partially filling the volume with a curable fluid, and curing the curable fluid.

Systems, devices and methods for control of a prosthetic or orthotic device (POD) based on electromyography (EMG) signals are described. The POD may be a lower or upper limb POD having one or more joints. One or more EMG sensors may detect the EMG signals. The EMG sensors may be external, subcutaneous, intraperitoneal, epimysial, intramuscular, or other types. Control of the POD may be based on EMG and non-EMG signals, such as velocity, acceleration, position, force, etc. Voluntary and/or automatic control may be implemented, for example with voluntary muscle contractions and/or data based on velocity, acceleration, position, force, etc. In some embodiments, the neutral position of an ankle POD is adjusted based on EMG signals.