An antenna assembly for use with a medical implant includes an antenna that defines at least one turn and an electromagnetic shield.

Systems and methods for performing non-obtrusive, automatic adjustment of an auditory prosthesis are disclosed. A control expression can be detected during a conversation. Upon detection of the control expression, an audio setting adjustment can be selected and applied to the auditory prosthesis. Multiple adjustments can be made in response to identifying multiple control expressions during a conversation.

An illustrative scalar translocation detection system directs a loudspeaker to apply acoustic stimulation to a cochlear implant patient while an electrode lead is inserted into a cochlea of the cochlear implant patient. The system detects a first evoked response to the acoustic stimulation while an electrode is positioned at a first location in the cochlea and detects a second evoked response to the acoustic stimulation while the electrode is positioned at a second location in the cochlea. Then, based on at least one of an amplitude change or a phase change between the first and second evoked responses, the system determines that a scalar translocation of the electrode lead from one scala of the cochlea to another scala of the cochlea has occurred. Based on this determination, the system also notifies a user that the scalar translocation has occurred. Corresponding methods and systems are also disclosed.

Presented herein are techniques for training a hearing prosthesis to classify/categorize received sound signals as either including a recipient's own voice (i.e., the voice or speech of the recipient of the hearing prosthesis) or external voice (i.e., the voice or speech of one or more persons other than the recipient). The techniques presented herein use the captured voice (speech) of the recipient to train the hearing prosthesis to perform the classification of the sound signals as including the recipient's own voice or external voice.

An apparatus includes a body configured to be at least partially implanted on or within a recipient and a plurality of electrodes positioned along the body. The plurality of electrodes includes a first set of electrodes configured to apply electrical stimulation signals to at least a portion of the recipient. The plurality of electrodes further includes a second set of electrodes configured to apply an electric field to cell membranes of the recipient, the electric field configured to increase a permeability of the cell membranes to a substance.

A hearing prosthesis system may include a cochlear implant coupled to an electrode array and configured to be implanted within a patient; and a processing unit communicatively coupled to the cochlear implant which is configured to direct the cochlear implant to apply stimulation to a cochlea of the patient via the electrode array and to detect, via the electrode array, a neural response of the patient to hearing stimulation. The processing unit is further configured to generate a user interaction audio signal indicative of an interaction of the patient with the hearing prosthesis system and apply perceivable hearing stimulation to the patient according to the user interaction audio signal, and to record, via the electrode array and the cochlear implant, the neural response to said hearing stimulation according to the user interaction audio signal, thereby utilizing the user interaction audio signal as a test audio signal.

Cochlear implant systems can include a cochlear electrode and a stimulator in electrical communication with the cochlear electrode. The stimulator can be in communication with a controller, which is in communication with a testing circuit and a switching network. The stimulator can include a plurality of source elements. The controller can control the switching network to place the plurality of source elements into communication with the testing circuit. The controller can further cause one of the plurality of source elements to emit an electrical current and can determine an amount of electrical current emitted from the source element using the testing circuit. The controller can compare the determined amount of electrical current emitted by the source element with a prescribed current. The controller can adjust the output of each of the plurality of source elements based on the determined amount of electrical current emitted by the stimulator.

An apparatus includes at least one housing configured to be implanted on or within a recipients body. The apparatus further includes first circuitry configured to wirelessly receive power from a device external to the recipients body, second circuitry configured to provide stimulation signals to a portion of the recipients body, and at least one power storage device having a discharged state in which the at least one power storage device is discharged to a voltage below a minimum operating voltage of the at least one power storage device. The apparatus further includes third circuitry configured to, while the at least one power storage device is in the discharged state, controllably distribute the power simultaneously to both the second circuitry and the at least one power storage device.

Systems and methods for detecting when a device is placed into an operational position are disclosed. Upon determination that the device is in the operational position, one or more processes can be executed. Execution or initialization of the processes upon detection of the operational position provides for the determination of optimal settings than would otherwise be determined if the processes automatically executed before detection of the operational position. Further aspects of the present disclosure relate to determining when the device is no longer in an operational position upon which time the execution of the processes are terminated. The settings in place upon termination can be saved and reapplied the next time the device is in the operational position.

An audio scene classifier classifies an audio input signal from an audio scene and includes a pre-processing neural network configured for pre-processing the audio input signal based on initial classification parameters to produce an initial signal classification, and a scene classifier neural network configured for processing the initial scene classification based on scene classification parameters to produce an audio scene classification output. The initial classification parameters reflect neural network training based on a first set of initial audio training data, and the scene classification parameters reflect neural network training on a second set of classification audio training data separate and different from the first set of initial audio training data. A hearing implant signal processor configured for processing the audio input signal and the audio scene classification output to generate the stimulation signals to the hearing implant for perception by the patient as sound.