Abstract: An electrode array design is provided which is intended for deep insertion into a human cochlea. The distal most portion of the lead can be very thin and flexible and have a wider arc than the remainder of the curved electrode array portion of the lead, which has a more aggressive arc. As a result, the distal most portion of the electrode array can be laterally positioned in a selected cochlear duct, whereas, concurrently, the remaining, more proximal part of the electrode array may be positioned medially (perimodiolar) within the cochlear duct.

Abstract: Optimizing pitch allocation in a cochlear stimulation system may include implanting an electrode array having a plurality of electrodes into the cochlea of a patient, where the electrode array has an associated implant fitting characteristic that defines a relationship between the implanted electrode array and audio frequencies, presenting sounds through the electrode array to the patient, receiving from the patient a selection of one of the sounds that most closely conforms to a single note, and determining a slope of the implant fitting characteristic of the electrode array based on the sound selected by the patient. Each sound may include a fundamental frequency and one or more harmonics. The optimization may also include changing a center frequency of a band pass filter associated with each electrode based on the determined slope.

Abstract: A cochlear stimulation lead and method of making a curved electrode array are provided. In one embodiment of the lead, while the curved section of the lead is curled further beyond its originally molded curvature and held in this position, a filling channel is filled with a filling material that is hardened or cured in this held position. The resulting lead has a tip curvature that is more curved than the originally molded curvature.

Abstract: Systems and methods for efficiently transmitting power using a high frequency (e.g., RF) telemetry transmitter are provided. The telemetry transmitter may include a fixed clock source (which may provide a fixed clock signal), telemetry phase shift circuitry (which may include switching circuitry and phase shifting circuitry), and a push-pull network. The telemetry phase shift circuitry generates a phase shifted clock signal that is phase shifted with respect to the fixed clock signal. The fixed and phase shifted clock signals may drive the switching circuitry to produce a high frequency signal that is passed through the push-pull network. The power or magnitude of the high frequency signal is based on the phase delay between the fixed clock signal and the phase shifted clock signal.

Abstract: A system for delivering therapeutic agents to biological tissue includes a surgically implantable lead configured to be inserted into the biological tissue, the surgically implantable lead including a preformed cavity; and a modular capsule containing a therapeutic agent which includes dexamethasone base; the modular capsule being secured within the preformed cavity; the modular capsule releasing the therapeutic agent into the biological tissue. A method of delivering therapeutic agents to biological tissue includes obtaining a surgically implantable lead with a preformed cavity; obtaining a modular capsule containing a therapeutic agent comprising dexamethasone base and securing it within the preformed cavity; and inserting the surgically implantable lead into the biological tissue.

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: Methods and systems for automatically detecting an impedance of one or more electrodes in a cochlear implant system include providing an implantable cochlear stimulator coupled to one or more electrodes, generating an electrical stimulation current with the implantable cochlear stimulator in accordance with stimulation parameters, automatically detecting an impedance of at least one of the electrodes in accordance with a predefined schedule, and performing a predefined action in accordance with the detected impedance.

Abstract: Systems and techniques for processing signals representative of sound for conveyance to the auditory system of a subject based on the identity of an input device. In one implementation, a method includes identifying an input element to an audiological system that conveys sound information directly to a subject's auditory system, automatically setting parameters for processing the signal based on the identity of the input element, and processing the signal in accordance with the processing parameters. The input element is configured to generate a signal representative of sound.

Abstract: A cochlear lead includes a plurality of electrodes configured to stimulate an auditory nerve from within a cochlea and a flexible body supporting the plurality of electrodes along a length of the flexible body. A stiffening element is slidably encapsulated within the flexible body, the stiffening element extending past a most distal electrode at the tip of the cochlear lead, wherein a distal portion of the stiffening element plastically deforms upon insertion into a curved portion of the cochlea.

Abstract: A process for manufacturing a single microcircuit into an integrated cochlear electrode array includes securing and supporting a nonconductive film substrate; attaching a metallic ribbon to a surface of the substrate; machining a flat multiconductor microcircuit from the ribbon to produce a flat elongated multiconductor tail portion with spaced outwardly exposed electrode receiving pads, and a flat multiconductor head portion connected to the tail portion and having spaced outwardly exposed attachment pads; laminating the flat microcircuit between the film substrate and an insulating cover; excising the laminated microcircuit from the film substrate with the electrode receiving pads exposed; wrapping the tail portion of the excised laminated microcircuit into a helix with the exposed electrode receiving pads wrapped around the insulating cover; mounting and electrically connecting the ring electrodes on and to the exposed electrode pads; and overmolding the helix tail portion with a polymeric material to read

Abstract: An implantable fixation assembly (30) for removably securing a (medical) device in a human body is disclosed. The assembly includes: an anchor portion (1) securable to bone; a pair of spaced apart legs (15), at least one leg (15) being resiliently flexible, the ends (15a) of the legs (15) attached to the anchor portion (1); a clamp portion (2) attached towards or at the ends (15a) of the legs (15); a screw and nut combination having an axis of rotation longitudinal to the legs, the combination operably engaging at least one of the legs (15) so as to pull them together or push them apart thereby actuating the clamp portion (2) to secure the device, wherein the actuating is reversible for selectively gripping and releasing the device.

Abstract: Errors in pitch allocation within a cochlear implant are corrected in order to provide a significant and profound improvement in the quality of sound perceived by the cochlear implant user. The disclosure provides a tool for determining the implant fitting curve for cochlear implant system to correct pitch warping. The method presents familiar musical tunes to determine the implant fitting slope (relative alignment). In addition, in one embodiment, speech sounds may be used to determine the offset of the fitting line (absolute alignment). The use of music and speech to determine the implant fitting curve (line) and the slope is facilitated by using techniques to implement virtual electrodes to more precisely direct stimuli to the location or “place” on the cochlea.

Abstract: A hearing prosthesis includes both a hearing aid adapted to sense and amplify low frequency acoustic sound signals and a cochlear implant system adapted to sense high frequency acoustic sound signals. The hearing aid has a first microphone adapted to sense the low frequency acoustic sound signals, amplify these sensed low frequency acoustic sound signals, and present the resulting amplified low frequency acoustic sound signals in the ear canal of a user, thereby enabling the user to better hear these amplified sounds using his or her normal hearing processes. The cochlear implant system includes a second microphone adapted to sense the high frequency acoustic sound signals and selectively stimulate the inner ear with electrical stimulation that will be perceived as high frequency acoustic sound signals. Both the cochlear implant system and the hearing aid system are coupled to operate on the same ear of the user.

Abstract: Alternative stimuli, i.e., stimuli other than the constant amplitude stimuli used in prior fitting schemes, are used to set the parameters of a hearing prosthesis, such as a cochlear implant system. The use of such alternative stimuli allows the entire fitting process to be completed in a very short time period, and generally eliminates the need for secondary adjustments. In one preferred embodiment, the alternative stimuli comprise white noise that is internally generated within the speech processor.

Abstract: An exemplary method includes 1) identifying, by a cochlear implant system, an electrode included within an array of electrodes as being a disabled electrode, 2) selecting, by the cochlear implant system, at least two non-adjacent electrodes surrounding the disabled electrode, and 3) simultaneously applying, by the cochlear implant system, stimulation current to the at least two non-adjacent electrodes to compensate for a loss of stimulation resulting from the disabled electrode. Corresponding methods and systems are also disclosed.

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: Methods of optimizing stimulation current applied to a cochlear implant patient include determining a plurality of narrowband spectral modulation detection thresholds for the patient and adjusting a stimulation current applied to the patient in accordance with the narrowband spectral modulation detection thresholds. Systems for optimizing stimulation current applied to a cochlear implant patient include an electrode array having a plurality of electrodes disposed thereon, an implantable cochlear stimulator coupled to the electrode array and configured to apply a stimulation current to one or more locations along a cochlea of a patient via one or more of the electrodes, and a fitting station communicatively coupled to the implantable cochlear stimulator. The fitting station is configured determine a plurality of narrowband spectral modulation detection thresholds and adjust the stimulation current in accordance with the narrowband spectral modulation detection thresholds.

Abstract: Methods of optimizing stimulation current applied to a cochlear implant patient include determining a plurality of narrowband spectral modulation detection thresholds for the patient and adjusting a stimulation current applied to the patient in accordance with the narrowband spectral modulation detection thresholds. Systems for optimizing stimulation current applied to a cochlear implant patient include an electrode array having a plurality of electrodes disposed thereon, an implantable cochlear stimulator coupled to the electrode array and configured to apply a stimulation current to one or more locations along a cochlea of a patient via one or more of the electrodes, and a fitting station communicatively coupled to the implantable cochlear stimulator. The fitting station is configured determine a plurality of narrowband spectral modulation detection thresholds and adjust the stimulation current in accordance with the narrowband spectral modulation detection thresholds.