A system is provided for driving an implantable neurostimulator lead, the lead having an associated plurality of electrodes disposed in at least one array on the lead. The system comprises an implantable pulse generator (IPG), the IPG including an electrode driver, a load system for determining load requirements, an IPG power coupler, and an IPG communication system. The system also includes an external unit, which includes an external variable power generator, an external power coupler, an external communication system, and a controller for varying the power level of the variable power generator.

Systems and methods for treating cognitive dysfunction and/or depression using transcutaneous auricular neurostimulation therapy may include positioning a wearable neurostimulation device about the ear of the patient, connecting the wearable neurostimulation device, to a pulse generator, and delivering a first series of stimulation pulses to at least one first electrode, the first series being configured to increase monoamine neurotransmitter availability, and delivering a second series of stimulation pulses to at least one second electrode, the second series being configured to upregulate opioid receptor agonists.

A system may include one implantable pulse generator and at least one implantable lead. The pulse generator may include a processor, a driving system for driving electrodes, a communication circuit, and a housing configured to be subcutaneously implanted. The lead may be configured to extend from the pulse generator to at least one neural target on a left side of a head and a neural target on a right side of the head. The lead may include at least two electrode sets, each including at least two electrodes. The lead be configured to be used to subcutaneously place the at least two electrode sets near the at least two neural targets, respectively, and electrically connect the pulse generator to each of the at least two electrodes sets to enable the driving system to drive the at least two electrode sets to stimulate the at least two neural targets.

Disclosed herein is a pulse generator device for trigeminal nerve stimulation. In one embodiment, the pulse generator device comprises a processor(s) configured to: produce pulses delivered to an electrode assembly for a therapy session(s) for a patient, log data from the therapy session(s) (where the data comprises impedance of the electrode assembly connected to the pulse generator and current amplitude of the pulses), determine an average current amplitude from the data, determine an average therapy impedance from the data, determine a charge capacity of a battery of the pulse generator prior to beginning a subsequent therapy session, determine whether the charge capacity of the battery is sufficient to complete the subsequent therapy session for a designated duration of time by using the average current amplitude and the average therapy impedance. Further the pulse generator device comprises a display configured to display a screen comprising a graphical user interface (GUI).

An implantable neurostimulator (INS) and method of use, the INS including an electrical lead having formed thereon at least a pair of bi-polar electrodes, wherein the electrical lead is configured for placement of the pair of bi-polar electrodes proximate protrusor muscles of a patient, a pulse generator electrically connected to the electrical lead and configured to deliver electrical energy to the pair of bi-polar electrodes, the pulse generator having mounted therein a sensor and a control circuit, and the sensor is configured to generate signals representative of an orientation of the pulse generator and communicate the signals to the control circuit and the control circuit is configured to determine the orientation of the pulse generator and deliver electrical energy to the bi-polar electrodes when the determined orientation correlates to a pre-determined orientation.

Techniques and electrode array designs can facilitate implantation of a vestibular electrode array proximate a target treatment location of the recipient’s vestibular system. An example vestibular electrode array can include a variety of mechanisms to provide fine control of the vestibular electrode array’s position in the vestibular space. Further, the position can be guided by real time feedback mechanisms, such as fluoroscopy or electrophysiological measures to assist with optimizing the position of the vestibular electrode array.

An implant unit delivery tool is provided. The implant delivery tool may include a body, a holder disposed at a distal end of the body and adapted to hold an implant unit, and an implant activator associated with the body, the implant activator configured to receive power from a power source. The implant activator may be configured to selectively and wirelessly transfer power from the power source to the implant unit during implantation of the implant unit into the body of a subject to cause modulation of at least one nerve in the body of the subject, and determine a degree of nerve modulation response resulting from the selective and wireless transfer of power from the power source to the implant unit claims.

A nerve stimulator according to one embodiment comprises: a pad member including a first pad portion arranged so as to come into contact with the auricle, and a second pad portion arranged so as to come in contact with the external auditory meatus; and a plurality of electrode members provided in the pad member so as to output electro-stimulation, wherein the plurality of electrode members can comprise: a first electrode member provided in the first pad portion so as to come into contact with the auricle; and a second electrode member provided in the second pad portion so as to come into contact with the external auditory meatus.

An implantable stimulator is provided having a conformable foil-like substrate, having a longitudinal axis extending from a pulse generator to a distal end of the substrate. The substrate comprising one or more adjacent polymeric substrate layers and an electrode array. The electrode array having a first and second electrode where one or more electrical interconnections are comprised in the substrate. The conformable foil-like substrate has a maximum thickness of 0.5 millimeter or less, proximate the electrodes. By providing a more easily patternable multilayer substrate, more complicated electrode array configurations may be supported, allowing a higher degree of flexibility to address transverse and/or longitudinal misalignment. By providing a relatively thin implantable electrode array user comfort may be increased through application of energy to tissue by the implantable stimulator.

A device to stimulate a scalp comprises an array of stimulating elements, the stimulating elements arranged along a circumference of at least one wheel, the wheel adapted to roll over the scalp. A method of treating/preventing a hair-condition comprises: subjecting the scalp to at least 200 distinct electrode-scalp contact events during a time-interval of at most one minute and dividable into 5 non-overlapping equal-duration sub-intervals covering the time-interval, method performed such that i. for at least a majority of the electrode-scalp contact events, no electrode of the event enters into the dermis; ii. a duration of each electrode contact event is at most 100 milliseconds; and iii. for each electrode contact event, an electrical current flows between the electrode and the scalp so as to deposit electrode-released ions of a first metal or of a second metal on the scalp, thereby forming a respective metal-ion-deposition island on the user's scalp.