Systems including intra-calvarial implants and/or subdermal implants are capable of stimulating cortical regions and sensing and electrical signals is implanted within or on a calvarial bone of a skull. The implants have current steering capability to change the current density profiles applied to selected cortical regions underlying the implant. The systems may track changes in the position and/or spatial parameters of a neural network by recording cortical electrical signals and processing them to compute the values of one or more network activity biomarkers. The systems may spatially track changes detected in network anatomical position and deliver the stimulation of the cortex to the network detected position by using current steering methods.

An example method includes delivering, via an electrical stimulation device, one or more electrical stimulation signals to a patient, sensing one or more stimulation-evoked signals that are evoked by stimulation of nerves or muscles of the patient due to the delivery of the one or more electrical stimulation signals, determining a quality of the one or more stimulation-evoked signals, and outputting, based on the quality of the one or more sensed stimulation-evoked signals being below a quality threshold, one or more instructions to improve the quality of one or more subsequent stimulation-evoked signals.

A system for collecting real-time on-demand measurements. The system includes an implantable sensor that has a power source, a sensing circuit, a communications circuit, a memory, and one or more processors. The sensing circuit senses a physiologic parameter of interest (PPOI) and generates signals indicative of the PPOI. The communications circuit communicates with at least one of an implantable medical device (IMD) or an external device (ED). The one or more processors execute program instructions stored in the memory to collect real-time on-demand measurements by activating the sensing circuit to generate the signals indicative of the PPOI, converting the signals to physiologic data indicative of the PPOI, storing the physiologic data in the memory, and directing the communications circuit to transmit the physiologic data to the at least one of the IMD or the ED.

An implantable medical device (IMD) has a housing enclosing an electronic circuit. The housing includes a first housing portion, a second housing portion and a joint coupling the first housing portion to the second housing portion. A polymer seal is positioned in the joint in various embodiments. Other embodiments of an IMD housing are disclosed.

Cochlear implant systems can comprise a cochlear implant system comprising a cochlear electrode, a stimulator in electrical communication with the cochlear electrode, a return electrode, and one or more controllers. The cochlear electrode can include a first contact electrode and the stimulator can include a first source element in electrical communication with the first contact electrode. The one or more controllers can be configured to cause the stimulator to emit a predetermined current from the first source element to the return electrode via a first current path and determine a first voltage at the first contact electrode and a second voltage at the return electrode. The one or more controllers can determine an impedance associated with the first current path and determine one or more stimulation parameters, such as a compliance voltage for sourcing a prescribed current, for the source element based on the determined impedance.

An electrode lead comprises an electrically insulative cuff body and at least three axially aligned electrode contacts circumferentially disposed along the inner surface of the cuff body when in the furled state. The electrode contacts may be circumferentially disposed around a nerve, and an electrical pulse train may be delivered to the electrode contacts thereby stimulating the nerve to treat obstructive sleep apnea. The electrical pulse train may be one that pre-conditions peripherally located nerve fascicles to not be stimulated, while stimulating centrally located nerve fascicles. A feedback mechanism can be used to titrate electrode contacts and electrical pulse train to the patient. A sensor that is affixed to the case of a neurostimulator can be used to measure physiological artifacts of respiration, and a motion detector can be used to sense tapping of the neurostimulator to toggle the neurostimulator between an ON position and an OFF position.

A cochlear implant headpiece, for use with a cochlear implant, including a housing, a diametrically magnetized headpiece magnet, defining an axis and a N-S direction, within the housing and rotatable about the axis, whereby the N-S direction of the headpiece magnet self-aligns with the gravitational direction when the axis is perpendicular to the gravitational direction, and a headpiece antenna associated with the housing.

The types of electrode leads that are connected to an implantable medical device are determined based on electrical parameters that are measured at the electrodes that are positioned on the leads. The different types of known electrode leads have different physical electrode arrangements that impact the measured electrical parameters. Properties in the measured electrical parameters that are indicative of the physical arrangements of electrodes of known types of electrode leads are utilized to determine the types of leads that are connected to the implantable medical device.

A system and/or method to control operation of an implantable medical device in response to sensed occurrence of a designated physical action intentionally performed by the patient.

Devices and methods for the stimulation of neural signalling of an apical splenic nerve, the device having a transducer for placement on or around the apical splenic nerve, and a signal generator to generate a signal that stimulates or inhibits the neural activity of the apical splenic nerve to produce a physiological response. The transducer has at least one electrode, and the signal generator is a voltage or current source. The stimulation electrical signal has a frequency of between 1 Hz and 50 Hz.