An implantable neurostimulator has an implantable electrode array comprising a plurality of stimulus electrodes. Each stimulus electrode is configured to deliver electrical stimuli to neural tissue. An implantable control module is configured to produce the electrical stimuli delivered by the stimulus electrodes, and is configured to effect current steering. The control module has a plurality of related current sources, each current source configured to deliver a respective stimulus current which is defined in a first part by a shared current control signal which is shared by each of the related current sources, and which is defined in a second part by a respective unique current control signal which is not shared by all of the related current sources.

An implantable stimulator is provided having a substrate comprising a conformable portion with an electrode array, and a pulse generator. A plurality of electrical interconnections are positioned between the surfaces of the substrate. The conformable portion has a thickness equal to or less than 0.5 millimeters. Optionally, one or more encapsulation layers may be provided. Optionally, one or adhesion layers may also be provided comprising a ceramic material.

By providing a more easily patternable 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. The one or more adhesion layers improve the performance of the encapsulation.

Vagal nerve stimulation devices and methods are provided for treating medical conditions, such as conditions associated with insufficient dopamine and/or endogenous opioids in the brain. A device includes one or more electrodes having a contact surface for contacting an outer skin surface of a patient and an energy source coupled to the electrodes. The energy source generates one or more electrical impulses and transmits the electrical impulses to the electrodes and transcutaneously through the outer skin surface of the patient at or near a vagus nerve. The one or more electrical impulses is sufficient to modulate the vagus nerve and release dopamine and/or endogenous opioids in a brain of the patient.

Systems and methods are disclosed for the treatment and prevention of migraine and other headache conditions, and more specifically to systems and methods of treating and preventing migraine and other headache conditions through noninvasive peripheral nerve stimulation.

A device for conveying power from a location external to a subject to a location within the subject may include a flexible carrier and an adhesive on a first side of the carrier. A coil of electrically conductive material may be associated with the flexible carrier. A mechanical connector may be associated with the carrier opposite the adhesive, wherein the mechanical connector is configured to retain a housing and permit the housing to rotate relative to the flexible carrier. At least one electrical portion may be associated with the carrier in a manner permitting electrical connection to be maintained between the flexible carrier and the housing as the housing is rotated.

An automated method of controlling neural stimulation. A neural stimulus is applied to a neural pathway in order to give rise to an evoked action potential on the neural pathway, and the stimulus is defined by at least one stimulus parameter. A neural compound action potential response evoked by the stimulus is measured. From the measured evoked response a feedback variable such as observed ECAP voltage (V) is derived. A feedback loop is completed by using the feedback variable to control the at least one stimulus parameter value for a future stimulus. The method adaptively compensates for changes in a gain of the feedback loop caused by electrode movement relative to the neural pathway. A compensating transfer function is applied to the feedback variable, the compensating transfer function being configured to compensate for both (i) a distance-dependent transfer function of stimulation, and (ii) a distance dependent transfer function of measurement which is distinct from (i).

An implantable restraint is provided that includes an opening, configured to receive a tissue anchor; a pair of protrusions between the opening and a distal edge, providing an anchor resistance to a longitudinal force; where the pair of protrusions are further configured to separate by a distance approximately equal to the tissue anchor when the longitudinal force exceeds a first predetermined threshold, such that the pair of protrusions moves past the tissue anchor.

By providing one or more openings extending through the substrate, the growth of tissue which naturally occurs after implantation is utilized to assist in securing the implantable restraint at the implantation site. By providing the pair of protrusions configured to provide resistance, a high degree of control of the restraining force and the explantation force is provided.

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.

A medical apparatus for a patient comprises an external system and an implantable system. The external system is configured to transmit one or more transmission signals, each transmission signal comprising at least power or data. The implantable system is configured to receive the one or more transmission signals from the external system, and to deliver stimulation energy to the patient. Methods of delivering stimulation energy are also provided.

The present invention relates to methods that enable one to design temporal patterns for the optimal stimulation of a nervous system, one or more nerve cells, or nervous tissue. In one embodiment, the present invention relates to methods to design improved stimulation patterns and/or genetic algorithms for the optimal stimulation of a nervous system, one or more nerve cells, or nervous tissue. In one embodiment, the present invention utilizes a model-based design to achieve a more optimal stimulation pattern for use in connection with a nervous system, one or more nerve cells, or nervous tissue (e.g., a human nervous system). In another embodiment, the model-based design of the present invention utilizes a systematic search method to identify parameters (e.g., design variables) that minimize a cost function (e.g., optimize the fitness of a particular design). In one instance, the system and method of the present invention is demonstrated via optimal temporal patterns of electrical stimulation for a nervous system, one or more nerve cells, or nervous tissue.