A device and method consisting of conductive, non-conductive, and support materials. These materials when dispensed or extruded onto a multitude of temporary structures will create an implantable conductive and non-conductive structure suitable for neurological electrical stimulation and neurological electrical recording. This structure may also be suitable for delivering fluid and/or contain optical structures suitable for physiological sensing.

Cochlear implant systems can include a cochlear electrode, a stimulator in electrical communication with the cochlear electrode, a sensor configured to receive a stimulus signal and generate an input signal based on the received stimulus signal, and a signal processor in communication with the stimulator and the sensor. In some examples, the stimulator and the signal processor are integrated into a single hermetically sealed housing. The housing can include a return electrode that extends from a first side of the housing to a second side of the housing opposite the first.

Cochlear implant systems can include a cochlear electrode, a stimulator in electrical communication with the cochlear electrode, a sensor configured to receive a stimulus signal and generate an input signal based on the received stimulus signal, and a signal processor in communication with the stimulator and the sensor. The signal processor can include an analog filtering stage configured to generate an analog filtered signal from a received input signal and a digital filtering stage configured to generate a digitally filtered signal from the analog filtered signal. The analog filtering stage and digital filtering stage can be used to normalize the frequency response of the digitally filtered signal with respect to the stimulus signal.

Systems can include a fully-implantable cochlear implant system having an input source, a signal processor, and an implantable battery and/or communication module. The system can include an externa hub having a speaker and a wireless communication interface. The external hub can be in wireless communication with the implantable battery and/or communication module. The external hub can be configured to output a predetermined acoustic signal via the speaker and communicate information to the implantable battery and/or communication module regarding the predetermined acoustic signal. The implantable battery and/or communication module can be configured to analyze information regarding the acoustic signal output from the external hub and information from the signal processor regarding the response of the cochlear implant system to the acoustic signal. Such analysis can be used to calibrate the cochlear implant system and detect stapedial reflexes in a wearer.

Cochlear implant systems can include first and second subsystems, each subsystem including an input source, a signal processor, a stimulator, and a cochlear electrode. A single implantable battery and/or communication module can provide power to and communicate with each subsystem, such as via each signal processor. Systems can include separate leads providing separate communication between the implantable battery and/or communication module and each subsystem, or can include a bifurcated lead providing signals to both subsystems simultaneously. The implantable battery and/or communication module can be configured to output addressed signals designating for which subsystem a signal is intended. The implantable battery and/or communication module can be configured to separately update settings associated with each respective subsystem, such as a transfer function associated with each signal processor.

Cochlear implant systems can include a near field communication device for communicating via a first wireless communication protocol and a wireless communication device for communicating via a second wireless communication protocol. An external device including an external near field communication device and an external wireless communication device can communicate with the implanted system via the first wireless communication protocol. Communication via the first wireless communication protocol can be used to enable communication between the implant system and the external device via the second wireless communication protocol. External devices can provide audio and/or data to the implant system via the second wireless communication protocol. External devices can include one or more sensors, and data from the sensors can be used to update a system transfer function based on the environment and/or location of the external device.

Cochlear implant systems can include a signal processor, an implantable battery and/or communication module, and a plurality of conductors coupling the implantable battery and/or communication module and the signal processor. The implantable battery and/or communication module can communicate data and deliver electrical power to the signal processor via the plurality of conductors. The implantable battery and/or communication module can be configured to perform characterization process to determine one or more characteristics of one or more such conductors. Characterization processes can include determining an impedance between two conductors as a function of frequency, determining whether a conductor is intact, and determining an impedance of a given conductor. Some characterization processes include grounding one or more conductors.

The invention relates to improvements in the field of medical electrical stimulation. An electromedical adapter, an electromedical electrode and an electromedical pulse generator are provided. In order to connect a non-coiled electrode portion (3) to a coiled electrode portion (2), in particular the adapter (1) is provided, having at least one contact element (5) which can be contacted by a coiled electrode portion (2) of an electrode (4) in such a way that the coiled electrode portion (2) surrounds, i.e. radially surrounds, a longitudinal axis of the main body (7) of the adapter with the at least one coiled conductor (8) thereof

Various aspects of the present disclosure are directed toward apparatuses, systems, and methods that include an implantable lead having a terminal pin, a conductor member configured to rotate in response to rotation of the terminal pin and a coupler arranged within configured to interface with the conductor member and having a rear bearing surface contacting the inner wall of a housing.

A lead body for implantation includes a first set of conducting sections, a second set of conducting sections, a strain relief coupler having a axial length with a plurality of tines extending along the axial length and extending radially thereby defining a plurality of axially-extending channels, a plurality of joints located within the plurality of channels, each joint coupling one conducting section from the first set of conducting sections to one conducting section from the second set of conducting sections, and an outer layer at least partially surrounding the first and second set of conducting sections, the plurality of joints and the strain relief coupler.