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 device to transmit an audio signal comprises at least one light source configured to transmit the audio signal with at least one wavelength of light. At least one detector is configured to detect the audio signal and generate at least one electrical signal in response to the at least one wavelength of light. A transducer is supported with and configured to vibrate at least one of an eardrum, an ossicle or a cochlea. Active circuitry is coupled to the transducer to drive the transducer in response to the at least one electrical signal, so as to provide the user with high quality sound.

Abstract: An output assembly is sized for placement in the middle and inner ear, such that removal of bone can be decreased. The output assembly may comprise at least one photo detector, a demultiplexer and an optical array sized to pass through an incision in the eardrum. An input transducer assembly is configured to transmit a multiplexed optical signal to the output assembly. The input assembly can be configured to transmit the multiplexed optical signal through the eardrum, such that tissue removal can be decreased and the device can be placed without removal of bone, for example. The multiplexed optical signal may comprise a pulse width modulated signal so as to decrease the effect of non-linearities of the light source and light detector and provide quality sound to the user.

Abstract: A hearing device can allow a user to determine from side which a sound originates with bone conduction vibration of the cochlea and the user can also receive sound localization cues from the device, as feedback can be substantially inhibited with bone conduction vibration of the cochlea. An output transducer assembly can be positioned on a first side of the user to vibrate a first bone tissue near a first cochlea with a first amount of energy, such vibration of a second cochlea on a second side with a second amount of energy is attenuated substantially, for example at least about 6 db, such that the user can localize the sound to the first side. A microphone may be located on the first side and coupled to the output transducer assembly, such that the user localizes the sound to the first side detects sound localization cues.

Abstract: A computer-implemented method including energizing an actuator of an auditory prosthesis with a driving signal, de-energizing the actuator, obtaining information indicative of a momentum-indicative parameter of the actuator while the actuator is de-energized, and evaluating the obtained information, and assessing actuator performance based on the action of evaluating.

Abstract: Systems and methods are disclosed for a hearing prosthesis, and more particularly to a hearing prosthesis with a rigidly coupled vibrating transducer. In embodiments, the mechanical stimulating hearing prosthesis comprises, for example, at least one sound input device configured to sense a sound signal, and a transducer configured to generate a vibration based on the sound, wherein the sound input device is rigidly coupled to the transducer. Systems and methods are also described for reducing a well-defined mechanical feedback generated by a transducer in a hearing prosthesis.

Abstract: The invention is directed to an implanted microphone having reduced sensitivity to vibration. In this regard, the microphone differentiates between the desirable and undesirable vibration by utilizing at least one motion sensor to produce a motion signal when an implanted microphone is in motion. This motion signal is used to yield a microphone output signal that is less vibration sensitive. In a first arrangement, the motion signal may be processed with an output of the implantable microphone transducer to provide an audio signal that is less vibration-sensitive than the microphone output alone. Specifically, the motion signal may be scaled to match the motion component of the microphone output such that upon removal of the motion signal from the microphone output, the remaining signal is an acoustic signal.

Abstract: According to an exemplary embodiment the hearing of a patient may be improved by providing the patient with a wearable package having a microphone, a wireless transmitter circuit responsive to the microphone to transmit a wireless transducer signal, a power storage device configured to provide power to the transmitter circuit; and a wireless power transmission circuit configured to transmit a wireless power signal and implanting into the patient an electrically powered microactuator having: a wireless receiver circuit to receive the wireless transducer signal; a transducer drive circuit coupled to the wireless receiver circuit to convert the received transducer signal into a transducer drive signal; a transducer coupled to the transducer drive circuit to convert the transducer drive signal into motion; and a wireless power reception circuit configured to receive the wireless power signal to power the transducer drive circuit.

Abstract: A method for adjusting parameters of a hearing prosthesis system includes adjusting a control to shift an audiogram associated with a first stimulator, applying a prescription rule using the shifted audiogram to adjust a cross-over frequency that defines a first frequency range and a second frequency range. The first stimulator is configured to apply stimulation signals in the first frequency range and a second stimulator is configured to apply stimulation signals in the second frequency range. The method also includes applying the prescription rule using the shifted audiogram to determine gain and maximum power output (MPO) levels for the first frequency range associated with the first stimulator.

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 hone structure, such as the maxillary, mandibular, or palatine bone structure.

Abstract: Systems and methods are disclosed for data transmission through a recipient's skull bone. In one aspect of the present technology there is provided a bilateral system, comprising a first mechanical stimulator configured to transmit first data through vibrations of a skull of a recipient, and a sensor device configured to receive the first transmitted data.

Abstract: A device, including an electromagnetic transducer including a bobbin having a space therein, a connection apparatus in fixed relationship to the bobbin configured to transfer vibrational energy directly or indirectly at least one of to or from the electromagnetic transducer, and a passage from the space to the connection apparatus.

Abstract: A transducer is configured to couple to the cochlear fluid so as to transmit sound with low amounts of energy, such that feed back to a microphone positioned in the ear canal is inhibited substantially. The cochlear fluid coupled hearing device can allow a user to determine from which side a sound originates with vibration of the cochlea and the user can also receive sound localization cues from the device, as feedback can be substantially inhibited. The transducer may be coupled to the cochlear fluid with a thin membrane disposed between the transducer and the cochlear fluid, for example with a fenestration in the cochlea. In some embodiments, a support coupled to the transducer directly contacts the fluid of the cochlea so as to couple the transducer to the cochlear fluid.

Abstract: Various embodiments of systems, devices, components, and methods are disclosed for a magnetic hearing aid system comprising an implantable sound transmission device configured for implantation in a patient's skull. The sound transmission device is configured to receive acoustic signals generated by an EM transducer in a magnetic hearing aid that are transmitted through the patient's skin, and to transmit the received acoustic signals to the patient's cochlea via one or more sound-transmitting metal members. According to some embodiments, the sound transmission device is curved to permit optimal placement of the hearing aid and corresponding magnetic implant behind a patient's ear.

Abstract: The present application discloses systems and methods to analyze feedback path information during a fitting session. In accordance with one embodiment, a method is provided and includes during a fitting session, calculating a feedback gain margin of a hearing prosthesis by causing the hearing prosthesis to receive a test signal, output an output signal based on the test signal, and receive a feedback signal based on the output of the output signal, the test signal being configured to test a different parameter of the hearing prosthesis.

Abstract: Disclosed are various embodiments of components and devices in a sound acquisition system for a magnetic hearing aid that include a sound acquisition device. In one embodiment, the sound acquisition device is configured to be positioned between a magnetic spacer and a magnetic implant, and to be magnetically coupled to the magnetic spacer and the magnetic implant, such that sound signals generated by an EM transducer in the hearing aid may be acquired by a sound sensor forming a portion of the sound acquisition device as the sound signals pass through the sound acquisition device into the patient's skull or a test fixture.

Abstract: A method and apparatus for providing therapy using spontaneous otoacoustic emission (SOAE) analysis is described. In one embodiments, a method for utilizing the voice-ear-brain connection to achieve self-healing includes capturing audio emissions of at least one ear of a patient, determining a frequency spectrum of the audio emissions, identifying a peak frequency in the frequency spectrum, and producing at least one audio signal in response the peak frequency.

Abstract: An integrated headpiece for a cochlear implant system includes a microphone for outputting an audio signal; signal processing electronics for processing the audio signal; and a transmitter for transmitting a processed audio signal received from the electronics to an implanted receiver. All of the microphone, signal processing electronics, and transmitter are disposed in a common housing of the integrated headpiece. The headpiece may also be one of a set of headpieces that can be alternatively used as needed to suit power consumption requirements or environmental conditions.

Abstract: A method for use in an implantable hearing instrument, including receiving an output signal from an implanted microphone implanted in a person, identifying a first characteristic of said output signal, based on said first characteristic, amplifying said microphone output signal by at least one of a plurality of gain settings to produce an amplified signal, wherein said plurality of gain setting comprise at least two different gain settings, inputting said amplified signal into a signal processor, processing said amplified signal to generate a transducer drive signal; and using said transducer drive signal to drive implanted auditory stimulation device implanted in a person to stimulate an auditory component.

Abstract: An implantable hearing prosthesis comprising a vibrator for generating vibrations, a coupling arm adapted to be attached to an element of a recipient's ear; and a quick-connector comprising a first connector half disposed on the vibrator and a second connector half disposed on the coupling arm, wherein the connector halves are adapted to be releasably mated with one another to secure the coupling arm in relative position to the vibrator.

Abstract: A bone conduction device, including a bone fixture adapted to be fixed to bone, a vibratory element adapted to be attached to the bone fixture and configured to vibrate in response to sound signals, and a vibration isolator adapted to be disposed between the vibratory element and the bone.

Abstract: Piezoelectric transducer arrays and methods of making the same are discussed. Such an array can include a piezoelectric film comprising a plurality of segments. Adjacent segments can be separated by trenches of a plurality of trenches in the piezoelectric film. Additionally, such an array can include a plurality of electrodes attached to the plurality of segments.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An external component for a hearing implant is described. An external housing contains an attachment magnet configured to magnetically connect with an implant magnet of an implanted signal transducer. A pair of external electromagnetic drive coils within the external housing are adjacent to the attachment magnet for conducting electrical current to develop magnetic drive signals through the skin to the signal transducer to generate responsive vibrations of the signal transducer for perception by the patient as sound. The drive coils are configured such that their respective magnetic drive signals have opposing magnetic directions.

Abstract: A middle ear transducer arrangement is described for engaging a round window membrane of a patient cochlea. A mechanical transducer is surgically implantable into a fixed position in the round window niche of the patient cochlea adjacent to the round window membrane. A drive face on the outer surface of the transducer has a diameter less than half the diameter of the round window membrane. The fixed position of the transducer engages the drive face against a side section of the round window membrane without engaging the center point to generate an acoustic stimulation signal for perception as sound.

Abstract: A test device for an ossicular prosthesis for implantation in the middle ear that includes a first fastening element, a second fastening element and a connecting element that connects the two fastening elements in a sound-conducting manner. Parts of the ossicular prosthesis are made of a material having memory effect and subjected to shape-altering thermal treatment at implantation. The test device also includes a device for determining an optimized power setting or an energy application site for preparing parts of the ossicular prosthesis to be subjected intraoperatively to thermal treatment using a prosthesis mock-up that is identical in design to the ossicular prosthesis in terms of material, geometric shape, and manufacturing method in the parts to be subjected intraoperatively to thermal treatment.

Abstract: A middle ear prosthetic device including: a columellate prosthesis, one end of which is connectable to the stapes or to its remaining footplate; an annular element of bioinert metal insertable into the auditory tube after suitable milling; an elastic elongated element of bioinert material, disposed transversely to the annular element, a first end of the elongated element being rigid with the annular element while its second end is free and to it there being connected the other end of the columellate prosthesis; for supporting the neotympanum, a tensostructure of wires of non-reabsorbable bioinert material fixed taut to the interior of the annular element to support the neotympanum, the distance between the wires being such as to provide the surgeon with a sufficient view of the surgical field, the elongated elastic element interfering with the tensostructure.

Abstract: A prosthesis including an abutment, an operationally removable component including a coupling apparatus, and an adapter, wherein the abutment is connected to the adapter and the coupling apparatus of the operationally removable component is releasably coupled to the adapter.

Abstract: A vibration sensor includes a substrate. A first electrical contact and a spaced apart second electrical contact are both disposed on a first surface of the substrate. The elongated piezoelectric nano-scale structure extends outwardly from the first surface of the substrate and is disposed between, and in electrical communication with, the first electrical contact and the second electrical contact. The elongated piezoelectric nano-scale structure is oriented so that a voltage potential exists between the first electrical contact and the second electrical contact when the elongated piezoelectric nano-scale structure is bent from a first state to a second state.

Abstract: A method and system of aligning antennas of an intra-oral and extra-oral electronic wireless device is provided. Three-dimensional anatomical data of at least a portion of an oral cavity of a subject and at least a portion of an external ear of the subject is recorded. A spatial relationship between a landmark in the oral cavity and a landmark in the external ear is determined. A first antenna is modeled based upon the anatomical data of the oral cavity, and a second antenna is modeled based upon the anatomical data of the external ear. The antennas are configured and oriented relative to each other for optimal signal transmission based upon the recorded anatomical data of the oral cavity and ear.

Abstract: A vibratory apparatus including a lever arm apparatus including a living hinge, wherein the vibratory apparatus is configured such that at least a portion of the lever arm moves about the living hinge when the vibratory apparatus is generating vibrations.

Abstract: An electromechanical actuator for an implantable hearing aid device including a mechanical output structure that has a first portion and a second portion, wherein the first portion is a mechanical attachment structure to attach a stapes prosthesis, and wherein the second portion is a wire-like member coupling the mechanical attachment structure to a magnetically permeable armature shaft assembly.

Abstract: The present application discloses systems, methods, and articles of manufacture for transferring data and/or data over a communication link. A medical device in one example includes receiver(s) configured to receive first signals, which include power signals and first stimulation data, and second signals, which include second stimulation data. Each of the first stimulation data and the second stimulation data includes data encoded according to a same data encoding protocol. The device also includes control circuitry coupled to the one or more receivers and configured to operate in a first mode and in a second mode. The control circuitry is configured in the first mode to apply the power signals to provide power to the medical device and to apply the first stimulation data to a medical device recipient. Further, the control circuitry is configured in the second mode to apply the second stimulation data to the medical device recipient.

Abstract: An implantable medical device having a hermetically-sealed biocompatible housing configured to be implanted in a recipient. The implantable medical device includes at least one trans-housing transformer configured to transfer electrical signals through the housing.

Abstract: A personal hearing aid (1) is adapted to be carried at the head of a person. The hearing aid comprises an EEG sensor part having electrodes (3) for measuring EEG responses from said person. The hearing aid comprises an EEG signal analyzer (5, 5?) adapted for having an EEG signal transferred from the EEG sensor part, and adapted for monitoring the EEG response. The hearing aid (1) further comprises EEG stimuli controlling means adapted for performing at least one of the following: providing a stimulus to the person, requesting the person to perform a stimuli creating act, or identifying a stimuli creating ambient sound. The hearing aid comprises EEG response detection means for identifying an induced response from the EEG response caused by the stimuli, and a classifier for deciding based on said induced response if the electrodes receive EEG responses. The invention further provides a method of adjusting a hearing aid.

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 second membrane has an opening that permits fluid to flow from the first volume to the second volume. The implantable microphone also includes a vibration sensor adjacent 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: A floating mass transducer has a cylindrical transducer housing within which is a cylindrical transducer magnet arrangement with a magnetic pair of: i. an inner rod magnet disposed along the cylinder axis with a first magnetic field direction, and ii. an outer annular magnet surrounding the inner rod magnet along the cylinder axis with a second magnetic field direction opposite to the first magnetic field direction. Current flow through the drive coils creates a coil magnetic field that interacts with the magnetic fields of the transducer magnet arrangement to create vibration in the transducer magnet which is coupled by the transducer housing to the middle ear hearing structure for perception as sound. In addition, the opposing magnetic fields of the transducer magnet arrangement cancel each other to minimize their combined magnetic field and thereby minimize magnetic interaction of the transducer magnet arrangement with any external magnetic field.

Abstract: A bone conduction hearing aid includes an in-the-ear (ITE) component including a transducer that is carried by the ITE component and positioned in the concha of the ear when in use. A vibrationally conductive structural member of the ITE component conducts vibration produced the transducer into the ear canal and such vibrations are transferred through a housing of the transducer. From there, the vibrations are transferred to a cochlea of the user by way of the mastoid bone, enabling enhanced hearing perception in patients with hearing loss.

Abstract: A transducer is configured to couple to the cochlear fluid so as to transmit sound with low amounts of energy, such that feed back to a microphone positioned in the ear canal is inhibited substantially. The cochlear fluid coupled hearing device can allow a user to determine from which side a sound originates with vibration of the cochlea and the user can also receive sound localization cues from the device, as feedback can be substantially inhibited. The transducer may be coupled to the cochlear fluid with a thin membrane disposed between the transducer and the cochlear fluid, for example with a fenestration in the cochlea. In some embodiments, a support coupled to the transducer directly contacts the fluid of the cochlea so as to couple the transducer to the cochlear fluid.

Abstract: A device to transmit an audio signal comprises at least one light source configured to transmit the audio signal with at least one wavelength of light. At least one detector is configured to detect the audio signal and generate at least one electrical signal in response to the at least one wavelength of light. A transducer is supported with and configured to vibrate at least one of an eardrum, an ossicle or a cochlea. Active circuitry is coupled to the transducer to drive the transducer in response to the at least one electrical signal, so as to provide the user with high quality sound.

Abstract: A hearing device can allow a user to determine from side which a sound originates with bone conduction vibration of the cochlea and the user can also receive sound localization cues from the device, as feedback can be substantially inhibited with bone conduction vibration of the cochlea. An output transducer assembly can be positioned on a first side of the user to vibrate a first bone tissue near a first cochlea with a first amount of energy, such vibration of a second cochlea on a second side with a second amount of energy is attenuated substantially, for example at least about 6 db, such that the user can localize the sound to the first side. A microphone may be located on the first side and coupled to the output transducer assembly, such that the user localizes the sound to the first side detects sound localization cues.

Abstract: Various embodiments of systems, devices, components, and methods are disclosed for magnetic spacers configured for use in conjunction with bone conduction hearing aids and corresponding magnetic implants. According to some embodiments, the magnetic spacers are configured to vary the amount and/or orientation or direction of magnetic coupling force provided thereby.

Abstract: Various embodiments of systems, devices, components, and methods are disclosed for magnetically coupling ferrous or magnetic spacers of bone conduction hearing aids to ferrous or magnetic bone screws or implants affixed to a patient's skull. In one embodiment, a spacer is provided that is configured to magnetically couple the hearing aid to an abutment and corresponding bone screw, or to an implanted ferrous or magnetic member, that is affixed to the patient's skull.

Abstract: Various embodiments of systems, devices, components, and methods are disclosed for adjustable bone conduction hearing aids where a patient or health care provided can select different positions of a magnetic spacer on a patient's skull after a magnetic implant has been implanted beneath the patient's skin and affixed to the patient's skull.

Abstract: Various embodiments of systems, devices, components, and methods are disclosed for mechanically coupling a bone conduction hearing aid, or a spacer or other device for a bone conduction hearing aid, to an abutment of a bone screw affixed to a patient's skull. Some embodiments of abutment attachment mechanisms employ axially-directed forces to secure a hearing aid to an abutment of a bone screw, while others employ radially directed forces to secure a hearing aid to an abutment of a bone screw.

Abstract: Various methods and apparatus for processing audio signals are disclosed herein. The assembly may be attached, adhered, or otherwise embedded into or upon a removable oral appliance to form a hearing aid assembly. Such an oral appliance may be a custom-made device which can enhance and/or optimize received audio signals for vibrational conduction to the user. Received audio signals may be processed to cancel acoustic echo such that undesired sounds received by one or more intra-buccal and/or extra-buccal microphones are eliminated or mitigated. Additionally, a multiband actuation system may be used where two or more transducers each deliver sounds within certain frequencies. Also, the assembly may also utilize the sensation of directionality via the conducted vibrations to emulate directional perception of audio signals received by the user. Another feature may include the ability to vibrationally conduct ancillary audio signals to the user along with primary audio signals.

Abstract: A wireless headset is adapted to communicate with a sound source such as a music player or a cell phone or a suitable audio or sound communicated through a one-way or two-way communication device. The headset includes a mouth wearable communicator; and a linking unit coupled to the mouth wearable communicator, the linking unit adapted to communicate with the sound source.

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: Evaluating an implanted hearing prosthesis, including operating the implanted hearing prosthesis, capturing sound generated by a transducer of the prosthesis during said operation, and comparing the captured sound to a sound model.

Abstract: Hearing systems for both hearing impaired and normal hearing subjects comprise an input transducer and a separate output transducer. The input transducer will include a light source for generating a light signal in response to either ambient sound or an external electronic sound signal. The output transducer will comprise a light-responsive transducer component which is adapted to receive light from the input transducer. The output transducer component will vibrate in response to the light input and produce vibrations in a component of a subject's hearing transduction pathway, such as the tympanic membrane, a bone in the ossicular chain, or directly on the cochlea, in order to produce neural signals representative of the original sound.