Presented herein are techniques for monitoring the physical state of a stimulating assembly to, for example, detect the occurrence of an adverse event. More specifically, an elongate stimulating assembly comprising a plurality of longitudinally spaced contacts is at least partially implanted into a recipient. Electrical measurements are performed at one or more of the plurality of contacts and the electrical measurements are evaluated relative to one another to determine the physical state of the stimulating assembly.

A method, including the action of executing a first evaluation including evaluating first interactions of respective current spreads with one another for a plurality of first electrodes implanted in a recipient resulting from energizement thereof with at least one second implanted electrode disabled, wherein the second electrode, if enabled and energized at about the same level as at least one of the first electrodes, would result in current spread to at least one of the plurality of first electrodes, and one of disabling at least one third electrode of the plurality of first electrodes based on the evaluation or maintaining an enablement of the nondisabled electrodes based on the evaluation.

Cochlear implant systems can include a cochlear electrode, a stimulator in electrical communication with the cochlear electrode, a sensor configured to receive a stimulus signal and generate an input signal based on the received stimulus signal, and a signal processor in communication with the stimulator and the sensor. The signal processor can include an analog filtering stage configured to generate an analog filtered signal from a received input signal and a digital filtering stage configured to generate a digitally filtered signal from the analog filtered signal. The analog filtering stage and digital filtering stage can be used to normalize the frequency response of the digitally filtered signal with respect to the stimulus signal.

An exemplary sound processor apparatus included in an auditory prosthesis system includes 1) an interface assembly that includes at least a first contact, 2) a first switchable current source having an output coupled to the first contact of the interface assembly by way of a first data line, 3) a differential transmitter having an output coupled to the first contact of the interface assembly by way of the first data line, 4) a differential receiver having an input coupled to the first contact of the interface assembly by way of the first data line, and 5) a control module communicatively coupled to the first switchable current source, the differential transmitter, and the differential receiver and configured to selectively operate in a component type detection mode and in a programming mode. Corresponding sound processor apparatuses, systems, and methods are also described.

A cochlear implant includes an electrode array having a plurality of electrode contacts arranged along at least a portion of a length of an electrode array, and a processing arrangement configured to map at least one electrode contact to first and/or second mappings. The first mapping provides a first electrical stimulation from the electrode contact to a first ground electrode positioned external to a patient’s cochlea to stimulate hearing at a first location in the cochlea positioned adjacent to the electrode contact when the implant is inserted into the cochlea. The second mapping provides a second electrical stimulation from the electrode contact to the second ground electrode to stimulate hearing at a location in the cochlea positioned further towards the apex of the cochlea as compared to a distal end of the electrode array when the implant is inserted into the cochlea.

Disclosed are wireless stimulation electrode for excitable tissue. In one example, a wireless stimulation electrode includes a body made of biocompatible photovoltaic and/or photothermal material; and at least one coating surrounding at least a portion of the body, wherein at least one critical dimension of the body is substantially smaller than a target cell. Also disclosed are systems and methods for stimulating excitable tissue.

According to an embodiment, a hearing aid system is disclosed. The system includes a speech processor communicatively coupled to a microphone. The speech processor is configured to process a microphone signal received at the speech processor for producing an electrical stimulation signal and an acoustic stimulation signal. The speech processor is also configured to generate a modified acoustic stimulation signal by modifying the acoustic stimulation signal at least for a part of a residual frequency range of a patient in dependence on effect of an implantable electrode array on mechanical properties of cochlea of the patient. The system also includes a first unit and a second unit. The first unit comprising a cochlear implant communicatively coupled to the speech processor, the cochlear implant comprising the implantable electrode array configured to be located within a cochlea of the patient and to provide the electrical stimulation based on the electrical stimulation signal to a cochlea within a non-residual frequency range of the patient. The second unit communicatively coupled to the speech processor and adapted to provide the modified acoustic stimulation based on the modified acoustic stimulation signal to the cochlea within the at least in the part of the residual frequency range.

A neural stimulator, suitable for implanting in a recipient, and configured to combine vagal nerve stimulation (VNS) with cochlear stimulation, to result in faster adaptation to new sounds and maps, and alleviation of tinnitus in the recipient.

An exemplary sound processor included in a cochlear implant system may include a control facility that represents a first frequency domain signal to a patient by 1) directing a cochlear implant included in the cochlear implant system to apply, during a first stimulation frame, a first monophasic stimulation pulse representative of a first temporal portion of the first frequency domain signal that corresponds to the first stimulation frame, the first monophasic stimulation pulse having a first polarity, and 2) directing the cochlear implant to apply, during a second stimulation frame that is temporally subsequent to the first stimulation frame, a second monophasic stimulation pulse representative of a second temporal portion of the first frequency domain signal that corresponds to the second stimulation frame, the second monophasic stimulation pulse configured to at least partially charge balance the first monophasic stimulation pulse and having a second polarity opposite the first polarity.

An apparatus and method for implanting and securing an implanted medical device in a recipient. The implantable medical device of the generally includes an electrode assembly that comprises an elongate carrier member having at least one stimulating electrode positioned thereon. The carrier member further has a fixation structure positioned thereon configured to interact with a portion of the rigid structure to longitudinally secure the carrier member in the recipient.