Abstract: Pedicle-based intradiscal fixation devices, systems, instruments, and methods thereof. A pedicle-based intradiscal implant for stabilizing an inferior vertebra and a superior vertebra may include a bendable rod configured to engage bone, a bone fastener defining a channel for receiving the bendable rod, and a locking cap for securing the bone fastener and the bendable rod. The implant may be positioned through a pedicle of an inferior vertebra and the bendable rod may be deployable into the vertebral body of the inferior vertebra, through the disc space, and into the vertebral body of the superior vertebra to stabilize the spine.

Abstract: An exemplary targeted channel selection system may determine a target stimulation rate for a user of a cochlear implant system, determine a pulse width value that is representative of one or more pulse widths that are to be used for stimulation pulses applied by the cochlear implant system to the user during a stimulation session, and determine, based on the target stimulation rate and on the pulse width value, a value for N that is specific to the user. In this example, N represents a total number of analysis channels that are to be selected from M available analysis channels for presentation by the cochlear implant system to the user during a stimulation frame of the stimulation session.

Abstract: An exemplary stimulation configuration management system may 1) obtain electric field imaging (EFI) data for a plurality of stimulation configurations associated with an electrode included in an intracochlear electrode array that is a part of a cochlear implant system associated with a patient, 2) identify, based on the EFI data, a stimulation configuration included in the plurality of stimulation configuration and that focuses an electric field produced by current applied to the electrode more than any other stimulation configuration included in the plurality of stimulation configurations, and 3) direct the cochlear implant system to use the identified stimulation configuration for the electrode during a normal operation of the cochlear implant system.

Abstract: An exemplary targeted channel selection system may determine a target stimulation rate for a user of a cochlear implant system, determine a pulse width value that is representative of one or more pulse widths that are to be used for stimulation pulses applied by the cochlear implant system to the user during a stimulation session, and determine, based on the target stimulation rate and on the pulse width value, a value for N that is specific to the user. In this example, N represents a total number of analysis channels that are to be selected from M available analysis channels for presentation by the cochlear implant system to the user during a stimulation frame of the stimulation session.

Abstract: Disclosed herein are embodiments of methods and systems for attenuating artifacts in single channel cochlear implants. Both high and low frequency artifacts can be attenuating using embodiments of the disclosed methods and systems. In some embodiments, low-pass filters, impedance balancing, and DC artifact estimation can be used, alone or in combination, to attenuate or completely remove artifacts in single channel cochlear implants.

Abstract: An exemplary stimulation configuration management system may 1) obtain electric field imaging (EFI) data for a plurality of stimulation configurations associated with an electrode included in an intracochlear electrode array that is a part of a cochlear implant system associated with a patient, 2) identify, based on the EFI data, a stimulation configuration included in the plurality of stimulation configuration and that focuses an electric field produced by current applied to the electrode more than any other stimulation configuration included in the plurality of stimulation configurations, and 3) direct the cochlear implant system to use the identified stimulation configuration for the electrode during a normal operation of the cochlear implant system.

Abstract: Disclosed herein are embodiments of methods and systems for attenuating artifacts in single channel cochlear implants. Both high and low frequency artifacts can be attenuating using embodiments of the disclosed methods and systems. In some embodiments, low-pass filters, impedance balancing, and DC artifact estimation can be used, alone or in combination, to attenuate or completely remove artifacts in single channel cochlear implants.

Abstract: An exemplary system includes an implantable cochlear stimulator implanted within a patient, a short electrode array coupled to the implantable cochlear stimulator and having a plurality of electrodes disposed thereon, and a sound processor communicatively coupled to the implantable cochlear stimulator. The sound processor may direct the implantable cochlear stimulator to apply a main current to a first electrode included in the plurality of electrodes and associated with a first pitch, direct the implantable cochlear stimulator to concurrently apply, during the application of the main current, a compensation current to a second electrode included in the plurality of electrodes and associated with a second pitch, and optimize 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.

Abstract: Embodiments of the present disclosure are directed to systems and methods for a closed-loop cochlear implant. The closed-loop cochlear implant can use at least one extra-cochlear electrode for monitoring auditory evoked potentials from the peripheral and central auditory pathway and stimulating to optimize speech processing. The closed-loop cochlear implant can further use at least one intra-cochlear electrode to stimulate the auditory nerve. Additionally, in some embodiments, the closed-loop cochlear implant can be used to monitor biosignals, such as EMG and ECG.

Abstract: An exemplary system includes an implantable cochlear stimulator implanted within a patient, a short electrode array coupled to the implantable cochlear stimulator and having a plurality of electrodes disposed thereon, and a sound processor communicatively coupled to the implantable cochlear stimulator. The sound processor may direct the implantable cochlear stimulator to apply a main current to a first electrode included in the plurality of electrodes and associated with a first pitch, direct the implantable cochlear stimulator to concurrently apply, during the application of the main current, a compensation current to a second electrode included in the plurality of electrodes and associated with a second pitch, and optimize 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.