A method for monitoring placement of a first physiologic sensor of a hearing device with respect to an ear of a user, the first physiologic sensor configured to monitor a heart rate of the user of the hearing device, includes: obtaining first physiologic sensor data from the first physiologic sensor at the hearing device; obtaining second physiologic sensor data from a second physiologic sensor at an external device, the second physiologic sensor configured to detect the heart rate of the user; performing a comparison based on the first physiologic sensor data from the first physiologic sensor, and the second physiologic sensor data from the second physiologic sensor; and setting a reference physiologic sensor data based on the first physiologic sensor data and/or the second physiologic sensor data if the comparison results in a match, or providing a notification if the comparison does not result in a match.

The invention relates to a method for setting up a controller of an orthopedic device with at least one motor drive, which is applied to a body part of the patient and connected to sensors that record control signals of the patient, said method including the following steps: outputting an optical, acoustic and/or tactile representation of an actuation of a limb as a request for the patient to carry out said actuation; detecting control signals that are produced by the patient as a voluntary reaction following the request, assigning the detected control signals to the implemented actuation and to a function in which the at least one motor drive is activated, deactivated or reversed in terms of its direction of rotation, and outputting the detected control signals and/or the function following the assignment to the respective function.

An intravascular device for placement within an animal vessel, the intravascular device being adapted to at least one of sense and stimulate activity of neural tissue located outside the vessel proximate the intravascular device.

A wearable device an intelligent health promotion service system (IHPSS) is disclosed. One embodiment of the wearable device (10) is configured to interface plurality groups of skin-mounted sensor pads (130) over a body part (140) of a wearer, and comprises: a modular brace (110) structurally separated from the sensor pads, and a plurality of sensor modules (120). The modular bracing is provided with a plurality groups of orienting slots (111) arranged thereon configured to maintain intra-group orientation between the sensor pads, and is configured to allow inter-group distance adjustment between the groups of the sensor pads over the body part of the wearer. The plurality of sensor modules is configured to be detachably coupled to the groups of sensor pads through the orienting slots in the modular bracing member. The sensor modules are provided with physiological sensing circuits wirelessly communicative with the intelligent health system.

A prosthesis system with a liner and a prosthesis socket, wherein the liner includes a closed distal end, an open proximal end, a lateral surface, which extends from the distal end to the proximal end, and a first connection device. The prosthesis socket includes a second connection device, which is configured to interact with the first connection device. The first connection device is arranged on the lateral surface, and the first connection device and the second connection device are configured to establish a mechanical locking and an electrical contact between the liner and the prosthesis socket.

A tracking device includes a housing that can be mounted to a patient or a prosthetic device or orthotic device of the patient. The tracking device can include communications circuitry, a position sensor, and processing circuitry. The position sensor is configured to detect position data regarding the patient. The processing circuitry is configured to receive the position data from the position sensor, determine one or more metrics regarding activity of the patient based on the position data, and use the communications circuitry to transmit at least one of the position data or the one or more metrics to a client device via the cellular network.

A mobility augmentation system monitors a user's motor intent data and augments the user's mobility based on the monitored motor intent data. A machine-learned model is trained to identify an intended movement based on the monitored motor intent data. The machine-learned model may be trained based on generalized or specific motor intent data (e.g., user-specific motor intent data). A machine-learned model initially trained on generalized motor intent data may be re-trained on user-specific motor intent data such that the machine-learned model is optimized to the movements of the user. The system uses the machine-learned model to identify a difference between the user's monitored movement and target movement signals. Based on the identified difference, the system determines actuation signals to augment the user's movement. The actuation signals determined can be an adjustment to a currently applied actuation such that the system optimizes the actuation strategy during application.

The present application describes apparatus (100) for locating an electrode unit on a prosthesis socket, comprising an electrode unit (102) locatable in a socket aperture (106) and having a first abutment surface (118) for engagement with an inner surface (120) of the socket; and a retaining element (104) locatable on the electrode unit and having a further abutment surface (126) for engagement with an outer surface (128) of the socket or the first abutment surface of the electrode unit.

A system and method for installing devices on a user can include an indicator set comprising a marker to place markings on the user, and a set of adhesive pads to be placed on the user. A knee pivot anchor can be attached to the user. A template having a proximal portion can be pivotally mounted to the knee pivot anchor. A distal portion of the template can be positioned at different locations on the user. The template also can have an aperture. A set of pods can be interchangeably located in the aperture of the template. Each pod can be secured to respective locations on the user. The template and the knee pivot anchor can be removed from the user with the pods remaining in place on the user to support a goniometer.

A photoplethysmography (PPG) sensor configured to be worn on a user's body, the PPG sensor comprising: a sensing portion comprising an optical emitter configured to emit an emitted light toward the user's body, and an optical detector for detecting a detector light reflected or scattered from the tissue, such as to provide a PPG signal; and an interfacing portion comprised between the sensing portion and the user's body, the interfacing portion comprising a transparent interface element through which the emitted light is transmitted when travelling from the optical emitter toward the body, and through which the detector light is transmitted when travelling from the body to the optical detector, wherein the transparent interface element has an interface transmittance; the transparent interface element comprising an antireflective interface being configured such that an antireflective interface transmittance of the transparent interface element comprising the antireflective interface is larger than the interface transmittance by at least 4%.