Abstract: An implantable microphone for use in hearing systems includes a housing having a sidewall, a first membrane coupled to a top portion of the housing and configured to move in response to movement from an auditory ossicle, and a second membrane coupled to the sidewall such that an interior volume of the housing is divided into a first volume and a second volume. The first volume has an opening that permits fluid to flow out from the first volume. The implantable microphone also includes a vibration sensor coupled to the second membrane and configured to measure the movement of the second membrane and to convert the measurement into an electrical signal. The vibration sensor may include a piezoelectric sensor and/or a MEMS sensor.

Abstract: Components and portions of components of a hearing prosthesis encapsulated in a microorganism-barrier membrane. Methods and apparatus are described for implanting hearing prosthesis components in precise locations, and maintaining the locations, with at least some components or portions of components encapsulated in a microorganism-barrier membrane.

Abstract: An auditory ossicle prosthesis (10) with a sound transmitting prosthesis body (13) has first and second coupling elements (11, 12) provided at opposite ends. A stabilizer element (14) fixes the prosthesis on a level with the plane of the tympanic membrane and stabilizes the position of the prosthesis in the middle ear. A fixation part (14.2) anchors the Y-shaped stabilizer element at one or more places of the ear canal wall. The fixation part includes two hooked anchoring elements (16) that secure the fixation part in artificially drilled holes in the ear canal wall. The auditory ossicle prosthesis has a particularly simple and compact design and stays spatially fixed within very small variations in its initial position after implantation inside the middle ear cavity, providing effective protection against post-operative dislocation, tilting or tipping and without deteriorating sound transmission properties of the prosthesis.

Abstract: An implantable microphone for placement in soft tissue, comprising a sensor arrangement comprising a housing, a first pressure sensor having a first membrane for being exposed to surrounding soft tissue and a second pressure sensor having a second membrane for being exposed to surrounding soft tissue and a compensation circuitry for combining the output signals of the first and second sensor in a manner so as to eliminate signals resulting from acceleration forces acting on the sensor arrangement, wherein the first and the second sensor are of a mirror-symmetric design with regard to each other, with the first and the second membrane being arranged parallel to each other.

Abstract: An implantable microphone, comprising a rigid housing, a sensor membrane for being exposed 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 implantable receptacle for receiving a hearing aid component includes a body having a proximal portion, a distal cylindrical portion and a joining portion joining the proximal portion to the distal cylindrical portion. First flexible tines extending from an outer wall of the distal cylindrical portion in the general direction of the proximal portion are configured to engage with and lock the distal cylindrical portion to a wall of a fenestration in a bone of the patient in a permanent fashion in response to pressing the sleeve into the fenestration. Second flexible tines extending from an outer wall of the distal cylindrical portion in a direction generally tangential to the circumference of the distal cylindrical portion are configured to engage with and prevent rotation of the distal cylindrical portion within the wall of the fenestration.

Abstract: A system for implantation in a recipient comprising: first and second functional implantable components configured to interoperate in order to stimulate the recipient's ear, and an implantable docking station having a plurality of interfaces, the interfaces comprising: a first interface configured to at least one of detachably mechanically and electrically connect to the first component, and at least a second interface configured to at least one of detachably mechanically and electrically connect to the second component, wherein one of the plurality of interfaces is configured to at least one of detachably mechanically and electrically connect to a third component, and wherein the third component is configured to perform an analogous function as one of the first and second components.

Abstract: A bone conduction device for enhancing the hearing of a recipient comprising a sound input element configured to receive an acoustic sound signal; an electronics module configured generate an electrical signal representing the acoustic sound signal; a transducer configured to generate mechanical forces representing the electrical signal for delivery to the recipient's skull; one or more extensions mechanically coupled at a first portion to the transducer and further mechanically coupled at a second portion of the one or more extensions to the recipient's bone, wherein the one or more extensions are configured to transfer the mechanical forces from the transducer to the recipient's bone.

Abstract: A hearing aid includes a magnetostrictive electroactive (ME) sensor that generates an electrical signal in response to a magnetic field or a mechanical pressure. In various embodiments, the ME sensor is used for cordless charging of a rechargeable battery in the hearing aid by generating an electrical signal in response to a magnetic field generated for power transfer, magnetic sound signal reception, and/or detection of user commands by sensing a magnetic field or a pressure applied to the hearing aid.

Abstract: An implantable hearing instrument is provided that reduces the response to unnaturally high vibrations (e.g., due to a patient's own voice), without necessarily or substantially affecting the response to desired signals. The implantable hearing instrument system is operative to selectively alter/lower the gain of signals that have a magnitude above a predetermined threshold. Signals having unnaturally large amplitudes (e.g., due to a patient's own voice) are amplified less than desired signals, so that a patient may experience a more representative sound.

Abstract: A multimodal auditory prosthesis. The prosthesis comprises a sound processing unit configured to process sound and to generate electrical signals representing different frequency components of the processed sound and a stimulation module communicably coupled to the sound processing unit, configured to stimulate the recipient to evoke a hearing percept of a range of the frequency components. The prosthesis also comprises an external stimulation module, configured to be positioned within an externally accessible portion of the recipient's first ear, comprising: a receiver unit to wirelessly receive the electrical signals representing the different frequency components, and a transducer that delivers acoustic or mechanical energy to the recipient's ear to evoke a hearing percept of a range of the frequency components.

Abstract: The present subject matter provides method and apparatus for hearing assistance devices, and more particularly to a system for evaluating hearing assistance device settings using detected sound environment. Various examples of a hearing assistance device and method using actual use and hypothetical use logs are provided. Such logs provide a dispenser or audiologist the ability to see how a device is operating with actual settings and how the device would have operated had hypothetical settings been used instead. In various examples, the system allows for collection of statistical information about actual and hypothetical use which can assist in parameter setting determinations for a specific user. The settings may be tailored to that user's commonly experienced sound environment. Wireless communications of usage logs is discussed. Additional method and apparatus can be found in the specification and as provided by the attached claims and their equivalents.

Abstract: An external component for a bone conduction hearing implant is described. An external housing is fixedly attached on the skin of a hearing implant patient over an implanted bone conduction hearing transducer. An electromagnetic drive coil arrangement is fixed within the external housing for conducting electrical current to develop electromagnetic drive signals. An attachment magnet arrangement is suspended with the external housing by a flexible spring arrangement and magnetically coupled to the drive coil arrangement and to a corresponding implant magnet arrangement within the implanted bone conduction transducer. The electromagnetic drive signals magnetically interact with the attachment magnet arrangement which reacts by vibrating on the spring arrangement and magnetically interacting with the implant magnet arrangement to generate a bone conduction vibration signal by the implanted bone conduction hearing transducer for perception by the patient as sound.

Abstract: An implantable magnetic transducer arrangement is described for a hearing implant in a recipient patient. An implant housing hermetically encapsulates an interior housing volume and is fixedly attached to skull bone beneath the skin of the patient. A magnetic transducer is located within the housing volume and includes multiple permanent magnets wherein adjacent magnets have opposite magnetic polarities, and one or more suspension elements that resiliently couple adjacent magnets to allow their relative movement. The magnetic transducer forms a coupled oscillating system with an external magnetic drive component above the skin of the patient to develop a mechanical stimulation signal to the implant housing for delivery by bone conduction of the skull bone as an audio signal to the cochlea of the patient.

Abstract: An arrangement is described for a hearing implant system. An implantable housing has an outer surface configured to lie under and parallel to the skin of the implanted patient. An implant magnet arrangement is located within the implantable housing and has multiple local magnetic sections with different independent local magnetic fields that are combined together to form a net magnetic field with at least two-fold symmetry and zero net magnetic dipole moment, wherein the magnetic fields are oriented parallel to the outer surface of the implant housing.

Abstract: The present invention relates generally to the design and optimal placement of transmitting and receiving directional antennas, a priori, as used in intra-oral to extra-oral (or visa versa) wireless electronic systems regardless of the type and purpose of the data transmitted between the antennas (intra-oral and extra-oral). Systems related to the invention transmit data via electromagnetic radio waves or through an inductive loop coupling such as in stimulating the human hearing nerve (inner ear) via dental bone conduction pathway when operating in “receive mode”. “Send mode” systems related to the invention transmit non-acoustic information or voice data from inside the mouth to a receiver located outside the mouth.

Abstract: A hearing prosthesis comprising an external component having an integrated user interface, a sound processor configured to process received sounds based on predefined fitting data, and an on-board fitting system configured to set the fitting data in response to control inputs received via the integrated user interface.

Abstract: A vibrator for generating vibrations in a bone conducting hearing device, i.e. a hearing device of the type in which the sound information is mechanically transmitted via the skull bone directly to the inner ear of a person. The vibratory movements are provided by a piezo-electric or magneto-elastic element arranged to transfer the vibrations via the skull bone from the area behind the outer ear to the inner ear. The piezo-electric or magneto-elastic element is arranged to be at least partially implanted in a surgically drilled hole directly into the mastoid bone behind the outer ear so that the vibrations are transferred directly from the element to the bone and transferred in the skull bone to the inner ear. The element is encapsulated with a bone integrating material, such as titanium or various biocompatible ceramic materials or coatings and is disc shaped and acts with a radial expansion upon electrical stimulation so that longitudinal sound waves are induced into the skull bone.

Abstract: A middle ear implant arrangement is described which includes an implantable electromechanical transducer with an inner end and an outer end, for converting an input electrical stimulation signal into a corresponding output mechanical stimulation signal. A cochlear engagement member at the inner end of the transducer has a cochlear engagement surface for coupling the mechanical stimulation signal to an outer cochlear surface of a recipient patient. A transducer loading structure has: i. an inner end adapted to releasably engage the transducer, ii. an outer end elongated along a central end axis for engaging a fixed anatomical structure within the middle ear of the recipient patient, and iii. a center spring structure connecting the inner end and the outer end and adapted to expand along a central spring axis to develop a spring force between the fixed anatomical structure and the outer end of the transducer.

Abstract: A bone conduction device, comprising: a sound input element configured to receive an acoustic sound signal; an electronics module configured generate an electrical signal representing said acoustic sound signal; and a transducer, comprising a mass configured to move in a rotational direction, configured to generate a vibrational force in a tangential direction with respect to a recipient's bone.

Abstract: There is provided an implantable actuator for direct stimulation of a patient's cochlea comprising a frame to be fluid-tightly fixed within the patient's oval window in a manner to replace the stapes footplate and having an oval shape conforming to the shape of the oval window, a rigid vibration element for acting on the perilymph fluid, which vibration element is guided within the frame, an elastic holding element fixed both at the frame and at the vibration element and extending laterally between the frame and the vibration element for allowing axial movement of the vibration element relative to the frame but preventing lateral movement of the vibration element relative to the frame, and a rod having a first end to be driven by the tympanic membrane, an ossicle or a driver of an at least partially implantable hearing aid and a second end connected to the vibration element for causing reciprocating movement of the vibration element within the frame.

Abstract: Methods and systems for treating tinnitus are provided. Some embodiments include a method of providing a primary audio signal having a primary peak portion substantially centered at about a tinnitus frequency of a patient. The method may also include combining the primary audio signal with a general audio signal to generate a combined sound. The method may also include exposing the patient to the combined sound so that the patient hears the combined sound, to diminish a perception by the patient of tinnitus.

Abstract: An electromechanical actuator (100) suitable, for example, in hearing aid applications is disclosed. Certain embodiments of the actuator comprise a hermetic titanium housing (1), a mechanical output structure (110) emulating the long process of incus (8), and means for efficiently generating movement in the audible frequency range. The electromechanical actuator (100) may be configured to be coupled to the inner ear fluids via a conventional stapes prosthesis. The implantable actuator (100), which may be considered to be operably equivalent to a loudspeaker of a conventional hearing aid, may bypass the outer and the middle ear in order to directly drive the inner ear fluids. As such, embodiments of the electromechanical actuator of the present invention may be used to remedy any source of conductive hearing loss.

Abstract: A bone conduction device configured to couple to an abutment of an anchor system anchored to a recipient's skull. The bone conduction device includes a housing and a vibrating actuator movably suspended in the housing and configured to vibrate in response to sound signals received by the bone conduction device The bone conduction device further includes a coupling apparatus configured to attach the bone conduction device to the abutment so as to deliver to the recipient's skull vibrations generated by the vibrating actuator, and a travel limit apparatus configured to limit a range of travel of the housing relative to the coupling apparatus.

Abstract: Methods and apparatus for transmitting vibrations via an electronic and/or transducer assembly through a dental implant are disclosed herein. The assembly may be attached, adhered, or otherwise embedded into or upon the implant to form a hearing assembly. The electronic and transducer assembly may receive incoming sounds either directly or through a receiver to process and amplify the signals and transmit the processed sounds via a vibrating transducer element coupled to a tooth or other bone structure, such as the maxillary, mandibular, or palatine bone structure.

Abstract: A microactuator has a proximal end configured to receive an electrical signal and a distal end configured to be inserted into a fenestration of an otic bone to provide access through the lateral wall of the cochlea of a subject. The microactuator includes a piezoelectric transducer assembly having a piezoelectric transducer disposed on a membrane (the piezoelectric transducer having a smaller dimension than a corresponding dimension of the membrane), a hermetically sealed fluid cavity filled with a fluid sealed at a first end to a first side of the piezoelectric transducer assembly and at a second end to a diaphragm, a second cavity containing a vacuum or a gas sealed at a first end to a second side of the piezoelectric transducer assembly and at a second end to an end cap.

Abstract: Methods and apparatus for transmitting vibrations via an electronic and/or transducer assembly through a dental patch are disclosed herein. The patch assembly may be attached, adhered, or otherwise embedded intra-orally on a tooth or oral tissue. The electronic and transducer assembly may receive incoming sounds either directly or through a receiver to process and amplify the signals and transmit the processed sounds via a vibrating transducer element coupled to a tooth or other bone structure, such as the maxillary, mandibular, or palatine bone structure.

Abstract: A method is described for providing sound perception in a hearing impaired patient. An externally generated electrical audio stimulation signal is received in a receiver unit located under the skin of an implanted patient. The electrical audio stimulation signal is delivered to an implanted bone conduction transducer having a planar bone engagement surface mounted to a temporal bone surface of the patient. The electrical audio stimulation signal is transformed into a corresponding mechanical stimulation signal coupled to the temporal bone by the bone engagement surface for delivery by bone conduction through the temporal bone to the cochlear fluid of the patient for perception as sound.

Abstract: An implantable component of a hearing prosthesis, including a bone fixture and one or more magnets, wherein at least one of the one or more magnets is disposed in a housing coupled to the bone fixture via a structure that extends from the housing to the bone fixture.

Abstract: A method including receiving input indicative of a parameter related to an operating environment of an implantable portion of a prosthesis and adjusting an adjustable system of the prosthesis based on the received input.

Abstract: A method for hermetically sealing electronic circuitry within a housing of an implantable medical device is provided. The method comprises assembling the housing having an interior cavity, joining a feed-through assembly to the housing, and joining a back-fill member to the feed-through housing. The back fill member has an opening there through communicating with the interior cavity of the housing. The housing is back-filled with an inert gas through the opening in the back-fill member, and the interior cavity is hermetically sealed by closing the opening through the back-fill member with a sealing element. The sealing element and back-fill member are formed of different first and second materials, respectively.

Abstract: A system and method are described for determining an estimated neural response in a hybrid electric acoustic audio prosthesis. Target nerve tissue such as remaining hair cells and cochlear nerve tissue receive synchronized electric and acoustic stimulation signals which are recorded and processed to determine an artifact canceled estimated neural response.

Abstract: An hearing prosthesis configured to cancel received bone-conducted sound. The hearing prosthesis comprises: first and second matched microphones configured to be implanted in a recipient in a spaced arrangement such that the first microphone receives air-conducted sound signals and bone-conducted sound signals substantially simultaneously, and wherein the second microphone receives bone-conducted sound signals at substantially the same time as the first microphone and receives the air-conducted sound signals after a time delay. The time delay results in a relative phase difference between the air-conducted sound signals and the bone-conducted sound signals received by the second microphone. The prosthesis also comprises a noise cancellation system configured to cancel, based on the phase difference, the bone-conducted sound signals received by the first and second microphones.

Abstract: An implantable hearing unit is provided that includes an implantable microphone, a rechargeable power storage device and a speech signal processor. The hearing unit further includes a signal coupling device that is adapted for electrical interconnection to an implantable auditory stimulation device, which is operative to stimulate an auditory component of a patient. Such a stimulation device may include cochlear implants, brain stem stimulation systems, auditory nerve stimulation systems, and middle or inner ear transducer systems. The signal coupling device is operative to provide processed drive signals from the signal processor to the stimulation device as well provide power from the power storage device to operate the stimulation device. In one arrangement, the signal coupling device is a wireless coupling between first and second coils. In such an arrangement, the hearing unit may be utilized with an existing implanted stimulation device to make that device a fully implanted hearing system.

Abstract: An implantable bone-conduction hearing actuator based on a piezoelectric element, such as a unimorph or bimorph cantilever bender, is described. Unlike other implantable bone conduction hearing actuators, the device is subcutaneous and once implanted is entirely invisible. The device excites bending in bone through a local bending moment rather than the application of a point force as with conventional bone-anchored hearing aids.

Abstract: The invention relates to a hearing aid device for humans with impaired hearing, who have an at least partially functional cochlea and a functional nervous signalling pathway from the cochlea via the auditory nerve to the brain. The hearing aid device contains a receiver, a transducer of the sound or other acoustic signals into electrical current serving as a signal representing a sound, a pulsed irradiation source connected to the transducer for receiving the electrical current and for generating modulated pulsed irradiation in dependence from the electrical current, and preferably one or more optical fibers optically coupled to the exit of the pulsed irradiation source, wherein the optical path for conduction of irradiation within the device ends directly opposite a functional element of the natural vibration transduction pathway, e.g.

Abstract: The application relates to: An acoustical transmission means for transmission of acoustical energy to the cochlea including: Liquid conducting assembly comprising a tube defining a bore therethrough and a liquid or semi-liquid medium filling said bore, for conducting acoustical energy there along; and said liquid conduction assembly terminated at and adapted to be disposed in direct operative association with the cochlea, for introducing said acoustical energy to the cochlear, Acoustic input means at said liquid conduction assembly.

Abstract: The present application discloses a vibration-based hearing prosthesis configured to measure the vibration applied by a hearing prosthesis to the skull of the hearing prosthesis recipient while the recipient is wearing the hearing prosthesis. Directly measuring the applied vibration in situ allows hearing characteristics to be more accurately mapped to voltage inputs. A recipient's hearing threshold and associated voltage input may be directly measured. Additionally, measuring the applied vibrations allows co-listening. A doctor can monitor the sound output from a vibration-based hearing prosthesis as it is worn by a recipient. Directly measuring the vibration output also allows an additional degree of freedom in diagnostics because a recipient can perform diagnostic tests at home.

Abstract: An apparatus for analyzing a sound signal is based on an ear model for deriving, for a number of inner hair cells, an estimate for a time-varying concentration of transmitter substance inside a cleft between an inner hair cell and an associated auditory nerve from the sound signal so that an estimated inner hair cell cleft contents map over time is obtained. This map is analyzed by means of a pitch analyzer to obtain a pitch line over time, the pitch line indicating a pitch of the sound signal for respective time instants. A rhythm analyzer is operative for analyzing envelopes of estimates for selected inner hair cells, the inner hair cells being selected in accordance with the pitch line, so that segmentation instants are obtained, wherein a segmentation instant indicates an end of the preceding note or a start of a succeeding note. Thus, a human-related and reliable sound signal analysis can be obtained.

Abstract: The invention relates to systems and methods for testing vestibular and oculomotor function. One aspect of the invention provides a vestibular and oculomotor function testing device including a track supported by a plurality of bearings, an engine configured to selectively displace the track, and a head coupling component coupled to the track. The head coupling component is configured to convey a movement generated by the engine to a subject's head in one or more axes.

Abstract: A bone conduction device, comprising: a sound input element configured to receive an acoustic sound signal; an electronics module configured generate an electrical signal representing said acoustic sound signal; and a transducer configured to generate motion of a mass component based on said electrical signal so as to generate one or more mechanical forces resulting in one or more of motion and vibration of a recipient's skull thereby causing sound perception, wherein one or more of the size and shape of said mass component is selectable at least partially based on a desired mechanical force to be generated by said transducer.

Abstract: An implantable component including an implantable body including a functional component of the implantable medical device, and implantable actuator positioning mechanism connected to and extending from the implantable body, the actuator positioning mechanism configured to removably receive an implantable actuator.

Abstract: The invention regards a method for determining a gain setting of a bone-anchored hearing aid comprising a bone anchor, the proximal and the distal ears having respective first and second monaural bone-conduction hearing thresholds, the first monaural bone-conduction hearing threshold being higher than the second monaural bone-conduction hearing threshold. The method comprises: obtaining respective first and second measured monaural bone-conduction hearing thresholds for the proximal and the distal ear; and determining the gain setting in dependence on the first and the second measured monaural bone-conduction hearing thresholds. The execution of the method does not require obtaining other hearing thresholds than such that are typically determined or measured anyway during the diagnostic phase.

Abstract: A cochlear implant system includes: an electrode array implanted within a cochlea; an internal processor in communication with the electrode array; an implanted antenna which is electrically coupled to the internal processor; and a modular external headpiece which is removably positioned over the implanted antenna, the modular external headpiece including a core containing a sound processor for processing sound and providing a corresponding signal to the implanted antenna; and a modular component configured to releasably engage the core and supply electrical power to the core.

Abstract: A hearing aid transducer adapts itself to variations in the surface of a tympanic membrane and slides over the migrating membrane without lubrication. Microscopic setae create a conforming interface between the biocompatible material of the transducer and the living tissue of the tympanic membrane.

Abstract: A bone conduction device, comprising: a sound input element configured to receive an acoustic sound signal; an electronics module configured generate an electrical signal representing said acoustic sound signal; and a transducer, comprising a mass configured to move in a rotational direction, configured to generate a vibrational force in a tangential direction with respect to a recipient's bone.

Abstract: A vibratory apparatus, including a housing having an internal chamber, wherein the internal chamber includes a lever having a first end and a free second end, and a piezoelectric element adapted to deform in response to an applied voltage, wherein deformation of the piezoelectric element displaces the free second end of the lever, and wherein displacement of the free second end of the lever within the internal chamber imparts a vibration to the housing.

Abstract: The invention relates to an electromechanical actuator 100 for hearing applications comprising one or more permanent magnets 10 and one or more magnetically permeable members 20 arranged to form a stator 50 and armature 70 arranged to provide one or more magnetic flux circuits 80, 80? configured to give rise, in the armature seat 52, to a position of unstable equilibrium for the armature 70 along the longitudinal A-A? axis and regions either side of the position of unstable equilibrium along the longitudinal A-A? axis where the armature applies a destabilization-driven force to the compliant member that decreases the effective rigidity of the compliant member that retains to armature in a neutral position. The invention also relates to a hearing aid system incorporating the electromagnetic actuator.

Abstract: A partially implantable hearing assistance system, having: an external unit (10) to be worn at least in part in a user's ear canal (12), a device (14) for capturing audio signals from ambient sound, an audio signal processing unit (16, 18) for generating first intermediate signals from said audio signals, and at least one electroacoustic output transducer (20, 20A) in order to make the user's eardrum (46) vibrate according to the first intermediate signals; and an implantable unit (22, 122) having an input transducer (42) located in the user's middle ear for capturing second intermediate signals from the vibration of the eardrum (46), an actuator (26, 60) for stimulating the user's hearing, and a driver unit (48, 148) for transforming the second intermediate signals into an input signal to the actuator (26, 60).

Abstract: A middle ear prosthesis device and corresponding implantation procedure are described. A sensing microphone converts an acoustic audio signal into a corresponding electrical audio signal. A sensing amplifier amplifies the electrical audio signal. An audio transducer converts the amplified electrical audio signal into a corresponding amplified acoustic audio signal. An acoustic waveguide conducts the amplified acoustic audio signal from the audio transducer to the middle ear and includes: i. a main tubular portion having an outer end for placement in the outer ear canal and an inner end for placement in the middle ear, and ii. an extension portion having an outer end coupleable to the audio transducer and an inner end coupleable to the outer end of the main tubular portion.