Abstract: An exemplary system includes 1) an electro-acoustic stimulation (“EAS”) sound processor configured to be located external to a patient, 2) a cochlear implant communicatively coupled to the EAS sound processor and configured to be implanted within the patient, 3) an electrode array communicatively coupled to the cochlear implant and configured to be located within a cochlea of the patient, and 4) a receiver communicatively coupled to the EAS sound processor and configured to be in communication with an ear of the patient. The EAS sound processor directs at least one of the cochlear implant and the receiver to apply stimulation to the patient, records an evoked response that occurs in response to the stimulation, and performs a predetermined action in accordance with the evoked response. Corresponding systems and methods are also disclosed.
Type:
Grant
Filed:
March 22, 2013
Date of Patent:
November 8, 2016
Assignee:
Advanced Bionics AG
Inventors:
Leonid M. Litvak, Smita S. Agrawal, Gulamali Emadi, Aniket Saoji, Charles C. Finley, R. Tissa Karunasiri, Kanthaiah Koka
Abstract: In one example, a cochlear lead includes a flexible body, an array of electrodes in the flexible body, and a plurality of wires passing along the array of electrodes. The plurality of wires includes a flexural geometry between each pair of adjacent electrodes and a substantially straight geometry over the electrodes. A method for forming an electrode array with a reduced apical cross section is also provided.
Type:
Application
Filed:
July 7, 2016
Publication date:
November 3, 2016
Applicant:
Advanced Bionics AG
Inventors:
Chuladatta Thenuwara, Rosa Gallegos, Lidia Vasquez, Mark B. Downing
Abstract: An auditory prosthesis device for neural stimulation of a patient's hearing having an audio signal input device; a sound processor for generating a neural stimulation signal; and an implantable stimulation assembly having plural stimulation channels for stimulation of the patient's hearing, the sound processor having a filter bank for dividing the input audio signal into plural analysis channels, each containing a frequency domain signal representative of a portion of the audio signal, a signal level determiner for each analysis channel for analyzing the respective frequency domain signal, a neural stimulation signal generator for each analysis channel, a mapping unit for allocating the analysis channels to the stimulation channels according to an adjustable mapping scheme, and a control unit for controlling the mapping unit such that a standard mapping scheme is used in a standard operation mode and a low bandwidth mapping scheme is used in a low bandwidth operation mode.
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: Exemplary insertion tools for facilitating insertion of an electrode array into a bodily orifice include a stylet assembly having a stylet configured to be inserted into a lumen of the electrode array, a slide assembly configured to at least partially house the stylet assembly, and a handle assembly configured to engage at least a portion of the slide assembly. The slide assembly may be configured to selectively disengage from the handle assembly. The stylet assembly may be configured to selectively disengage from the slide assembly while the stylet is still inserted into the lumen of the electrode array. Corresponding systems and methods are also described.
Type:
Grant
Filed:
April 17, 2009
Date of Patent:
October 25, 2016
Assignee:
Advanced Bionics AG
Inventors:
William G. Orinski, Steve J. Blomquist, Mark B. Downing
Abstract: An exemplary cochlear implant includes a communication facility configured to receive at least a first data word and a second data word in series from a sound processor by way of a forward-telemetry link and a processing facility communicatively coupled to the communication facility and configured to 1) use the first data word to dynamically determine an address associated with an electrode by way of which a stimulation pulse is to be applied during a time slot of a stimulation frame and 2) use the second data word to determine an amplitude of the stimulation pulse that is to be applied by way of the electrode during the time slot of the stimulation frame. Corresponding systems and methods are also disclosed.
Abstract: An implantable microphone, comprising a rigid housing, a sensor membrane for exposure to surrounding soft tissue, the sensor membrane being arranged to seal an opening of the housing, a transducer for generating an output signal corresponding to the deflection of the sensor membrane, and a compliant suspension arrangement located opposite to the sensor membrane for being exposed to soft tissue and for supporting the housing on soft tissue in a manner that the housing is moveable relative to said soft tissue upon acceleration of the housing and the soft tissue, the suspension arrangement comprising means for adjusting the spring constant of the suspension arrangement when the microphone is implanted.
Abstract: An exemplary cochlear electrode array includes a flexible body having a pre-curved spiral shape so as to conform with the curvature of a human cochlea, a plurality of stimulation electrode contacts spaced apart along a first side of the flexible body, a bundle of wires embedded within the flexible body for electrically connecting the electrode contacts to at least one stimulation signal source, at least one inflatable portion extending along at least part of the length of the flexible body, the at least one inflatable portion being adapted to straighten the flexible body, starting from the pre-curved shape, prior to insertion into the cochlea upon being inflated by being filled with gas or liquid, and to allow the flexible body to gradually reassume its pre-curved shape during insertion of the flexible body into the cochlea upon gradual withdrawal of gas or liquid from the at least one inflatable portion.
Type:
Grant
Filed:
September 4, 2014
Date of Patent:
September 20, 2016
Assignee:
Advanced Bionics AG
Inventors:
Hassan Alshehri, Abdulrahman Hagr, Patrick Joseph Boyle, Volkmar Hamacher
Abstract: An exemplary system includes a sound processor that 1) determines a relative importance of performance versus power conservation for an auditory prosthesis, 2) determines, in accordance with the determined relative importance of performance versus power conservation, a current steering range for a stimulation channel defined by first and second physical electrodes communicatively coupled to the auditory prosthesis, the current steering range centered about a midpoint of the stimulation channel; and 3) directs the auditory prosthesis to apply electrical stimulation representative of audio content having a frequency included in a frequency band associated with the stimulation channel in accordance with the determined current steering range.
Abstract: An exemplary system includes 1) a stimulation management facility configured to direct an electro-acoustic stimulation (“EAS”) system to concurrently apply acoustic stimulation to a patient by way of a loudspeaker and electrical stimulation to the patient by way of an electrode located within a cochlea of the patient during a fitting session, and 2) a fitting facility communicatively coupled to the stimulation management facility and configured to detect, during the fitting session, an interaction between the acoustic stimulation and the electrical stimulation, and set, during the fitting session, one or more control parameters governing an operation of the EAS system based on the detected interaction. Corresponding systems and methods are also disclosed.
Abstract: An exemplary system for facilitating binaural hearing by a cochlear implant patient includes 1) a spectral analysis facility configured to divide a first audio signal presented to a first ear of the patient and a second audio signal presented to a second ear of the patient into first and second sets of analysis channels, respectively, and 2) a processing facility configured to process acoustic content contained in a first analysis channel included in the first set of analysis channels and acoustic content contained in a second analysis channel included in the second set of analysis channels, mix the processed acoustic content contained in the first and second analysis channels, and direct a cochlear implant to apply electrical stimulation representative of the mixed acoustic content to the first ear by way of a stimulation channel that corresponds to the first analysis channel.
Type:
Grant
Filed:
December 29, 2011
Date of Patent:
September 13, 2016
Assignee:
Advanced Bionics AG
Inventors:
Lakshmi N. Mishra, Leonid M. Litvak, Abhijit Kulkarni, Lee F. Hartley
Abstract: A system for retaining a magnet in a cochlear implant, comprising a retainer embedded within an encapsulant of the cochlear implant, and a magnet case engaged with the retainer. A retainer for retaining a magnet within a cochlear implant comprising a number of first fasteners that couple with a number of corresponding second fasteners of a magnet case hermetically sealing the magnet, and a number of supports embedded within an encapsulant of the cochlear implant.
Abstract: A system having a device for neural stimulation of a patient's cochlea, an in-situ device for measuring a patient's response to the neural stimulation of the cochlea, and a programming unit for adjusting the stimulation device; the stimulation device having a stimulation signal unit for generating a stimulation signal formed of pulses having a shape determined by a shape parameter set including at least one shape parameter; a cochlear implant stimulation arrangement with a plurality of stimulation channels for stimulating the cochlea based on the stimulation signal; the measuring device providing patient-specific response data concerning the stimulation response to a programming unit that controls the stimulation signal unit by subsequently supplying a plurality of different test shape parameter sets to the stimulation signal unit for causing the stimulation signal unit to generate corresponding test pulses, the programming unit evaluating each test shape parameter set based on stimulation response data.
Abstract: An exemplary method of fitting a sound processor to a cochlear implant patient includes pre-loading program data representative of a plurality of sound processing programs onto a sound processor during a data transfer session and selectively using, after completion of the data transfer session, one or more of the pre-loaded sound processing programs to fit the sound processor to the patient. Corresponding methods and systems are also described.
Abstract: An exemplary headpiece module includes 1) a housing configured to be affixed to a head of a patient, 2) communication circuitry disposed within the housing and that facilitates communication of an off-the-ear sound processor module with a cochlear implant implanted within the patient, and 3) a loudspeaker at least partially disposed within the housing of the headpiece module and that applies acoustic stimulation to the patient as directed by the off-the-ear sound processor module.
Abstract: An exemplary sound processor 1) sets a current steering range for a stimulation channel defined by first and second physical electrodes communicatively coupled to an auditory prosthesis to be less than an entire physical range of the stimulation channel, 2) maps each frequency included in a frequency band associated with the stimulation channel to a virtual electrode included in a plurality of virtual electrodes included in the current steering range of the stimulation channel, 3) identifies a feature of an audio signal, 4) identifies a virtual electrode included in the plurality of virtual electrodes and that is associated with the identified feature, and 5) directs the auditory prosthesis to apply electrical stimulation representative of the identified feature to a stimulation site associated with the identified virtual electrode by concurrently stimulating the first physical electrode with a first current level and the second physical electrode with a second current level.
Abstract: The stimulation provided in the electrically stimulated cochlea is modulated in accordance with the amplitude of a received acoustic signal and the onset of a sound in a received acoustic signal to provide increased sound perception. An onset time that corresponds to the onset of a sound is detected in an acoustic signal associated with a frequency band. A forcing voltage and a transmitting factor are determined, wherein the forcing voltage and the transmitting factor are associated with the frequency band at the detected onset time. The acoustic signal is modulated as a function of the forcing voltage and the transmitting factor to generate an output signal. The generated output signal can be used to stimulate the cochlea. The modulation strategy can be used in conjunction with sound processing strategies that employ frequency modulation, amplitude modulation, or a combination of frequency and amplitude modulation.