Techniques for providing an indication of coupling between medical devices are disclosed. For example, when a programming device and a telemetry module are coupled, the telemetry module provides a first indication, and the programming device provides a second indication substantially similar to the first indication. The indications may be, for example, colors, and different indications may signify communication with different implantable medical devices, programming different therapies, or use of different applications of the programming device.

Described here are stimulation systems and methods for stimulating one or more anatomical targets in a patient for treatment conditions such as dry eye. The stimulation system may include a controller and a microstimulator. The components of the controller and microstimulator may be implemented in a single unit or in separate devices. When implemented separately, the controller and microstimulator may communicate wirelessly or via a wired connection. The microstimulator may generate pulses from a signal received from the controller and apply the signal via one or more electrodes to an anatomical target. In some variations, the microstimulator may include a passive generation circuit configured to generate a pulse based on a signal received from the controller.

The present invention changes the magnet-mode of an active implantable medical device (AIMD) using a static strip magnet comprising at least a first, second and third magnet. The electronic circuits of the AIMD have been programmed to register when the static strip magnet has been swiped across the AIMD so that when the magnetic field-detection sensor detects a defined north and south polarity sequence of the first, second and third magnets, the electronic circuits have been programmed to enter into magnet-mode with electrical stimulation therapy of the body tissue and/or electrical sensing of biological signals from the body tissue being suspended, maintained in a preset mode, or placed in a programmed mode.

Provided is an effective stereognosis training system that integrates hardware and software to provide a simple, reliable, quantitative system to provide tactile rehabilitation and progress monitoring. The system can include an interactive device including a novel set of objects, that are combined with neuromodulatory systems such as wireless closed-loop vagus nerve stimulation to improve neural plasticity and expedite functional recovery. The system can send updates to therapists or clinicians to monitor progress and encourage compliance with prescribed therapy.

An exemplary cochlear implant assembly includes a cochlear implant configured to apply electrical stimulation to the recipient by way of an electrode array, a cochlear implant antenna communicatively coupled to the cochlear implant, and an encapsulant that covers the cochlear implant and the cochlear implant antenna, the encapsulant impregnated with a dielectric material that is configured to confine an electric field around the cochlear implant antenna. Corresponding methods for manufacturing cochlear implant assemblies are also described.

An implantable system for stimulating a human heart or an animal heart, comprising a first stimulation unit and a first detection unit, wherein the first stimulation unit is used to stimulate at least one cardiac region of a human or an animal heart, and wherein the first detection unit is used to detect an electrical signal of at least one cardiac region of the same human or animal heart. The system comprises a first timer, which is used to provide a defined delivery of stimulation pulses, in terms of time, by the first stimulation unit. The system comprises a second timer, which is provided and configured to match a delivery point in time of at least one pulse to be delivered by the second stimulation unit to a delivery point in time of at least one pulse to be delivered by the first stimulation unit.

The embodiment discloses an electrode array including a housing; a plurality of first contact electrodes exposed to an outside of the housing; a plurality of second contact electrodes exposed to the outside of the housing; a first wire group disposed inside the housing and electrically connected to the first contact electrodes; and a second wire group disposed inside the housing and electrically connected to the second contact electrodes, the plurality of first contact electrodes and the first wire group being disposed on different planes within the housing.

A signal processor is described for communication with an implanted medical device. An external processor transmits to the implanted medical device an implant data signal having a sequence of HI and LOW logic states at a fixed data bit rate. The pulse width durations of the HI and LOW logic states is adjustable in response to feedback telemetry data from the implantable medical device.

Techniques facilitating locating an implantable medical device (IMD) within a body of a patient are provided. An estimate of the location is determined based on strength information representative of strengths of communicative couplings between a communications head device and the IMD at various positions of the communications head device. The strength information can be updated periodically or based on specific events, such as changes to the body and/or an amount of time elapsed since strength information was previously obtained. Media representative of the estimate of the location and an image of the body can be output and can facilitate a patient or caregiver locating the IMD. In some embodiments, the media and image output can guide future placement of the communications head device on the patient to efficiently establish communication. Further, in some embodiments, numerous IMDs implanted within a single body can be identified and communication can commence.

An external device of a prosthesis, including an electronics component, which can be a sound processor of a hearing prosthesis, and a power component, which can be a battery, the power component being removably attached to the electronics component, wherein the BTE device is configured with electrostatic discharge protection between the electronics component and the power component.