Abstract: An exemplary system includes at least one computing device that 1) detects a user input command for a sound processor included in a cochlear implant system to perform one or more cochlear implant fitting operations, wherein the sound processor is communicatively coupled to the at least one computing device by way of a communication path, 2) directs, in response to the user input command, the sound processor to perform the one or more cochlear implant fitting operations, and 3) transmits, in response to the user input command, a signal to the sound processor by way of the communication path, the signal configured to direct the sound processor to display a visual cue prior to or simultaneously with the performance of the one or more cochlear implant fitting operations. Corresponding systems and methods are also described.

Abstract: An exemplary system includes 1) a sound processor configured to divide an audio signal into a plurality of analysis channels, wherein each of the analysis channels contains information corresponding to a distinct frequency band of the audio signal, and wherein one of the analysis channels contains fine structure information corresponding to the audio signal, and 2) an implantable cochlear stimulator configured to generate electrical stimulation in accordance with the information contained within each of the analysis channels, apply the electrical stimulation to at least one stimulation site within a patient via a plurality of stimulation channels, each of the stimulation channels corresponding to one of the analysis channels and configured to convey the information contained within the analysis channels to the patient via at least one electrode, and at least partially isolate one of the stimulation channels from a rest of the stimulation channels.

Abstract: An exemplary method includes 1) applying a main current to a first electrode disposed within a patient and associated with a first pitch, 2) concurrently applying a compensation current to a second electrode disposed within the patient and associated with a second pitch during the application of the main current, the compensation current being out-of-phase with the main current, and 3) optimizing an amount of the compensation current to result in a target pitch being presented to the patient that is distanced from the first pitch in a pitch direction opposite a pitch direction of the second pitch in relation to the first pitch. Corresponding methods and systems are also disclosed.

Abstract: Apparatus and methods for converting one type of speech processor unit into another type of speech processor unit.

Abstract: Exemplary insertion tools, systems, and methods for inserting a pre-curved electrode array portion of a lead into a bodily orifice are described herein. An exemplary insertion tool includes a handle assembly, a slider assembly, an insertion assembly coupled to the handle assembly, and a retractor assembly disposed at least partially within the handle assembly and configured to selectively couple to a straightening member inserted into the pre-curved electrode array portion and at least partially retract the straightening member from the pre-curved electrode array portion in response to actuation by a user of the slider assembly. The retractor assembly may comprise a spring-loaded retractor member configured to move from a distal position to a proximal position in response to actuation by the user of the slider assembly to at least partially retract the straightening member from the pre-curved electrode array portion. Corresponding insertion tools, systems, and methods are also described.

Abstract: An exemplary signal processing unit includes 1) a microphone configured to detect one or more acoustic signals, 2) processing circuitry configured to process the one or more acoustic signals, and 3) a port configured to receive one or more electrodes that are configured to be placed on an outer surface of the head of a patient and to detect one or more central auditory potentials. The processing circuitry may be further configured to process the detected central auditory potentials.

Abstract: Exemplary insertion tools, systems, and methods for inserting an electrode array portion of a lead into a bodily orifice are described herein. An exemplary insertion tool includes a handle assembly, a slider assembly, a retractor assembly disposed at least partially within the handle assembly, and a rocker lever. The retractor assembly may include a stiffening member configured to be inserted into the electrode array portion and a spring-loaded retractor member coupled at a proximal end of the stiffening member. The spring-loaded retractor member may be configured to move from a distal position to a proximal position to at least partially retract the stiffening member from the electrode array portion. The rocker lever may be configured to selectively retain the spring-loaded retractor member in the distal position. Corresponding tools, systems, and methods are also described.

Abstract: A method for forming a cochlear electrode array with a plurality of electrodes which are spaced so as to stimulate sites within a cochlea includes shaping a sheet of electrically conductive material to form a support structure and a plurality of electrodes, in which the electrodes are tethered to the support structure at the spacing of the cochlear electrode array. A cochlear lead includes a flexible body that has frictional characteristics that vary about its circumference. A cochlear lead includes a flexible body with a first region and a second region with different surface textures. This generates differential sliding forces during insertion of the cochlear lead which influence a motion of the cochlear lead during insertion. The cochlear lead having an electrode array with varying stiffness along its length is also provided.

Abstract: An exemplary electro-acoustic stimulation (“EAS”) system (100) includes 1) an off-the- ear sound processor module (102), 2) a headpiece module (104) communicatively coupled directly to the off-the-ear sound processor module (102) and configured to be affixed to a head of a patient, the headpiece module (104) comprising a housing with communication circuitry disposed therein that is configured to facilitate communication by the off-the-ear sound processor module (102) with a cochlear implant (106) implanted within the patient, and 3) a loudspeaker (110) communicatively coupled directly to the headpiece module (104). The off-the-ear sound processor module (102) is configured to direct the cochlear implant (106) to apply electrical stimulation to the patient and direct the loudspeaker (110) to apply acoustic stimulation to the patient. Corresponding systems, devices, and methods are also disclosed.

Abstract: Sound processors and systems including sound processors are disclosed.

Abstract: An exemplary method includes a sound processing unit 1) directing an implantable cochlear stimulator to apply a plurality of stimulation pulses each having a first pulse width by way of a plurality of electrodes during a first stimulation frame, the plurality of electrodes including a first electrode and a set of remaining electrodes, 2) detecting a change in impedance of the first electrode, 3) adjusting, in response to the change in impedance of the first electrode, a pulse width parameter associated with the first electrode to define a second pulse width, and 4) directing the implantable cochlear stimulator to apply a stimulation pulse having the second pulse width by way of the first electrode and a plurality of stimulation pulses having the first pulse width by way of the set of remaining electrodes during a second stimulation frame subsequent to the first stimulation frame.

Abstract: An exemplary system includes a sound processing unit configured to apply noise reduction to an audio signal in accordance with a noise reduction parameter, an implantable cochlear stimulator communicatively coupled to the sound processing unit and configured to apply stimulation representative of the noise reduced audio signal to a patient via one or more electrodes, and a user input facility communicatively coupled to the sound processing unit and that facilitates manual adjustment of the noise reduction parameter.

Abstract: An exemplary method includes 1) detecting, by an auditory prosthesis configured to be implanted in a patient, a communicative coupling of a sound processor to the auditory prosthesis, the sound processor configured to be located external to the patient, and 2) logging, by the auditory prosthesis, data associated with an operation of the sound processor while the sound processor is communicatively coupled to the auditory prosthesis. Corresponding auditory prostheses and systems are also disclosed.

Abstract: A cochlear lead includes a plurality electrodes forming an electrode array configured to stimulate an auditory nerve from within a cochlea; a lead body connected to the electrode array; a plurality of wires passing through the lead body and connecting to the plurality of electrodes; an integrated wire carrier extending between an exit of the wires from the lead body and a first electrode in the electrode array, the integrated wire carrier comprising a cavity along its longitudinal axis configured to contain the plurality of wires and shape the plurality of wires into a wire bundle in which the plurality of wires passing through the integrated wire carrier are substantially parallel to the longitudinal axis of the integrated wire carrier; and a flexible body encapsulating the integrated wire carrier and the wires.

Abstract: An exemplary method of facilitating adjustment of one or more fitting parameters by an auditory prosthesis patient includes 1) receiving, by a fitting subsystem communicatively coupled to a sound processor, user input representative of a selection of a fitting parameter, 2) associating, by the fitting subsystem in response to the user input, the fitting parameter with a physical input mechanism that is a part of the sound processor, and 3) dynamically adjusting, by the fitting subsystem, a value of the fitting parameter in response to actuation by a user of the physical input mechanism. Corresponding methods and systems are also described.

Abstract: An exemplary auditory prosthesis system includes an auditory prosthesis configured to be implanted within a head of a patient and to apply electrical stimulation representative of an audio signal to one or more stimulation sites within the patient in accordance with one or more stimulation parameters, a behind-the-ear sound processing unit configured to be secured to an ear of the patient and to transmit the one or more stimulation parameters to the auditory prosthesis, and a remote audio processor module separate from the behind-the-ear sound processing unit and communicatively coupled to the behind-the-ear sound processing unit via a communication link, the remote audio processor module configured to perform at least a portion of a signal processing heuristic on the audio signal in order to facilitate generation of the one or more stimulation parameters.

Abstract: An exemplary cochlear implant system includes an external module configured to be positioned external to and worn by a patient, the external module having an external microphone configured to detect an input audio signal presented to the patient, and an external speaker configured to acoustically transmit an audio signal representative of the input audio signal. The exemplary cochlear implant system further includes an implantable module configured to be implanted within the patient, the implantable module having an internal microphone configured to detect the acoustically transmitted audio signal, an internal sound processor configured to generate one or more stimulation parameters based on the acoustically transmitted audio signal, and an internal cochlear stimulator configured to apply electrical stimulation representative of the input audio signal to one or more stimulation sites within the patient in accordance with the one or more stimulation parameters.

Abstract: An exemplary method of acoustically controlling a cochlear implant system includes acoustically transmitting, by a remote control subsystem, a control signal comprising one or more control parameters, detecting, by a sound processing subsystem communicatively coupled to a stimulation subsystem implanted within a patient, the control signal, extracting, by the sound processing subsystem, the one or more control parameters from the control signal, and performing, by the sound processing subsystem, at least one operation in accordance with the one or more control parameters. Corresponding methods and systems are also described.

Abstract: The invention relates to a template for implanting a housing of an implantable unit of a partially implantable hearing instrument, comprising a template plate comprising an implant position marking opening and a template position indicating element which extends substantially normal with regard to the surface of the template plate, wherein the implant position marking opening is designed to mark the position of a receptacle to be created in the patient's temporal bone for receiving an elevated housing positioning portion of the housing, and wherein the template position indicating element is a projection designed to be seen or felt by a surgeon through the patient's skin when the template plate is positioned at the patient's skull to mark the position of said receptacle.

Abstract: An exemplary method includes an electro-acoustic stimulation (EAS) system associated with a user 1) processing sounds sensed by a first microphone coupled to a cochlear implant portion of the EAS system, 2) applying electrical stimulation representative of the sounds sensed by the first microphone by way of a plurality of electrode contacts located in a basal region of a cochlea of the user, 3) processing sounds sensed by a second microphone coupled to a hearing aid portion of the EAS system, 4) broadcasting, way of a speaker, amplified sound signals representative of the sounds sensed by the second microphone into an ear canal of the user, and 5) acoustically separating the second microphone from the speaker to avoid feedback within the hearing aid portion of the EAS system. Corresponding methods and systems are also disclosed.