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: A system for mechanically assisted insertion of an electrode includes: an insertion tool configured to insert the electrode into biological tissues; and a controller configured to control the insertion tool, in which the controller is further configured to select operating parameters comprising a maximum allowable force profile from a library of operating parameters, in which the maximum allowable force profile is generated from data recorded during a number of previous successful operations. Also, a method for insertion of a cochlear lead, includes: selecting operating parameters comprising a maximum allowable force profile from a library of operating parameters; inserting the cochlear lead while sensing real time force and position; and continuing the insertion while the real time force is below the maximum allowable force profile, in which the maximum allowable force profile is generated from data recorded during a number of previous successful operations.

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: A system for delivering a therapeutic agent to biological tissue includes a surgically implantable lead to be inserted into the biological tissue. The surgically implantable lead includes a preformed cavity. A modular capsule is configured to be retained within the preformed cavity. The modular capsule includes a first therapeutic agent and a second therapeutic agent, wherein the first therapeutic agent elutes rapidly into the biological tissue and the second therapeutic agent elutes more slowly into the biological tissue.

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: 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: A method for delivering dexamethasone base (DXMb) via an implantable electrode includes coupling DXMb to the implantable electrode and inserting the implantable electrode into animal tissue, the DXMb eluting into the animal tissue. An implantable nerve stimulating device includes an elongated member having a distal end bearing at least one electrode; and DXMb coupled to the elongated member, the DXMb being eluted into tissue surrounding the elongated member.

Abstract: Methods and systems for modifying the parameters of at least one hearing device for a patient with residual hearing provide needed orchestration of acoustic and electric stimulation of patients wearing such devices.

Abstract: Methods and systems for modifying the parameters of at least one hearing device for a patient with residual hearing provide needed orchestration of acoustic and electric stimulation of patients wearing such devices.

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 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: Errors in pitch (frequency) 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. In one embodiment, the user is stimulated with a reference signal, e.g., the tone “A” (440 Hz) and then the user is stimulated with a probe signal, separated from the reference signal by an octave, e.g., high “A” (880 Hz). The user adjusts the location where the probe signal is applied, using current steering, until the pitch of the probe signal, as perceived by the user, matches the pitch of the reference signal, as perceived by the user. In this manner, the user maps frequencies to stimulation locations in order to tune his or her implant system to his or her unique cochlea.

Abstract: Errors in pitch (frequency) 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. In one embodiment, the user is stimulated with a reference signal, e.g., the tone “A” (440 Hz) and then the user is stimulated with a probe signal, separated from the reference signal by an octave, e.g., high “A” (880 Hz). The user adjusts the location where the probe signal is applied, using current steering, until the pitch of the probe signal, as perceived by the user, matches the pitch of the reference signal, as perceived by the user. In this manner, the user maps frequencies to stimulation locations in order to tune his or her implant system to his or her unique cochlea.

Abstract: Methods of automatically identifying whether a neural recording signal includes a neural response signal include fitting an artifact model to a neural recording signal to produce a fitted artifact model signal, determining a strength-of-response metric that describes a distance of the neural recording signal from the fitted artifact model signal, and identifying the neural recording signal as including a neural response signal if the strength-of-response metric is above a pre-determined threshold. Corresponding systems are also described.

Abstract: Errors in pitch (frequency) 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. In one embodiment, the user is stimulated with a reference signal, e.g., the tone “A” (440 Hz) and then the user is stimulated with a probe signal, separated from the reference signal by an octave, e.g., high “A” (880 Hz). The user adjusts the location where the probe signal is applied, using current steering, until the pitch of the probe signal, as perceived by the user, matches the pitch of the reference signal, as perceived by the user. In this manner, the user maps frequencies to stimulation locations in order to tune his or her implant system to his or her unique cochlea.

Abstract: A system for mechanically assisted insertion of an electrode includes: an insertion tool configured to insert the electrode into biological tissues; and a controller configured to control the insertion tool, in which the controller is further configured to select operating parameters comprising a maximum allowable force profile from a library of operating parameters, in which the maximum allowable force profile is generated from data recorded during a number of previous successful operations. Also, a method for insertion of a cochlear lead, includes: selecting operating parameters comprising a maximum allowable force profile from a library of operating parameters; inserting the cochlear lead while sensing real time force and position; and continuing the insertion while the real time force is below the maximum allowable force profile, in which the maximum allowable force profile is generated from data recorded during a number of previous successful operations.

Abstract: An exemplary method of conveying fine structure information to a cochlear implant patient includes dividing an audio signal into a plurality of analysis channels, generating electrical stimulation in accordance with the information contained within each of the analysis channels, applying the electrical stimulation to at least one stimulation site within a patient via a plurality of stimulation channels, and at least partially isolating one of the stimulation channels from a rest of the stimulation channels, wherein fine structure information is conveyed to the patient via the isolated stimulation channel. Corresponding methods and systems are also disclosed.

Abstract: A bionic ear cochlear stimulation system has the capability to stimulate fast enough to induce stochastic neural firing, thereby acting to restore “spontaneous” neural activity. Such neurostimulation involves the use of a high rate pulsitile stimulation signal that is amplitude modulated with sound information. Advantageously, by using such neurostimulation, a fitting system may be utilized that does not normally require T-level threshold measurements. T-level threshold measurements are not required in most instances because the high-rate pulsitile stimulation, even though at levels that would normally be a sub-threshold electrical stimulus, is able to modulate neural firing patterns in a perceptible way.

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 multichannel cochlear implant system spatially spreads the excitation pattern in the target neural tissue by either: (1) rapid sequential stimulation of a small group of electrodes, or (2) simultaneously stimulating a small group of electrodes. Such multi-electrode stimulation stimulates a greater number of neurons in a synchronous manner, thereby increasing the amplitude of the extra-cellular voltage fluctuation and facilitating its recording. The electrical stimuli are applied simultaneously (or sequentially at a rapid rate) on selected small groups of electrodes while monitoring the evoked compound action potential (ECAP) on a nearby electrode. The presence of an observable ECAP not only validates operation of the implant device at a time when the patient may be unconscious or otherwise unable to provide subjective feedback, but also provides a way for the magnitude of the observed ECAP to be recorded as a function of the amplitude of the applied stimulus.

Abstract: Methods and systems for modifying the parameters of at least one hearing device for a patient with residual hearing provide needed orchestration of acoustic and electric stimulation of patients wearing such devices.