A method for optimization of the stimulation pattern of a set of implanted electrodes in excitable tissue of a patient is disclosed, wherein it comprises the steps of: (a) choosing a first group of a certain number of from said set of implanted electrodes, (b) stimulating the excitable tissue electrically by said first group of electrodes, (c) registering information provided by the patient, (d) assigning each electrode of said first group of electrodes a value related to said information, wherein these steps are repeated for one or more further groups of said certain number of electrodes chosen from said set of implanted electrodes, wherein each electrode may be included in one or several groups, wherein the total assigned value for each electrode is calculated, and wherein electrodes having a total assigned value exceeding a predetermined value or a predetermined number of the electrodes having the highest total assigned value are chosen to be included in said stimulation pattern, as well as a method for treatment or alleviation of a disease or condition by use of a set of electrodes whose stimulation pattern has been optimized with said method, and a system for optimization of the stimulation pattern.

Programming a stimulator device to deliver a stimulation therapy at high-density parameter settings using a cathode-minimized electrode configuration determined to induce paresthesia over a patient pain pattern at low-density parameter settings.

An electric stimulator for heart (as in heart pacemakers), brain (as in DBS), organs and general cells, with electrodes in the space surrounding the main stimulating electrodes. These surrounding electrodes are more effective at creating the best electric field to guide the stimulating electric charges necessary for the purpose of the device. The surrounding electrodes are supported on a second supporting device, while the main electrodes are in a first supporting device we call picafina.

An Implantable Pulse Generator (IPG) or External Trial Stimulator (ETS) system is disclosed that is capable of sensing an Evoked Compound Action Potential (ECAP), and (perhaps in conjunction with an external device) is capable of adjusting a stimulation program while keeping a location of a Central Point of Stimulation (CPS) constant. Specifically, one or more features of measured ECAP(s) indicative of its shape and size are determined, and compared to thresholds or ranges to modify the electrode configuration of the stimulation program.

A neurostimulation device has at least three stimulation electrodes configured to deliver an electrical stimulus to neural tissue. A control unit is configured to deliver a first stimulus phase in which a first stimulus electrode delivers a supra-threshold stimulus component, returned by at least two other of the stimulation electrodes. The control unit is further configured to deliver at least a second stimulus phase in which at least two of the stimulus electrodes deliver a sub-threshold stimulus component, returned by the first stimulus electrode.

A method for enhancing muscle function of skeletal muscles in connection with a planned spine surgery intervention in a patient's back is provided. The method includes implanting one or more electrodes in or adjacent to tissue associated with one or more skeletal muscles within a back of a patient, the one or more electrodes in electrical communication with a pulse generator programmed for enhancing muscle function of the one or more skeletal muscles. Electrical stimulation is delivered, according to the programming during a time period associated with the planned spine surgery intervention, from the pulse generator to the tissue associated with the one or more skeletal muscles via the one or more electrodes, thereby improving neuromuscular control system performance of the one or more spine stabilizing muscles in connection with the planned spine surgery intervention to reduce the patient's recovery time associated with the planned spine surgery intervention.

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).

This document discusses, among other things, systems and methods for delivering electrostimulation to specific tissue of a patient. An example of a system can receive a three-dimensional voxelized model representing a plurality of regions each specified as a target region or an avoidance region. The system includes control circuitry to determine a metric value using the voxelized model. The metric value indicates a clinical effect of electrostimulation on the plurality of regions according to a stimulation current and a current fractionalization. The control circuitry can determine a desired stimulation current that results in a first metric value satisfying a clinical effect condition. The system can generate a stimulation configuration including the desired stimulation current and the current fractionalization corresponding to the first metric value, and deliver tissue stimulation according to the stimulation configuration.

This application is generally related to systems and methods for providing a medical therapy to a patient by tracking patient activity and adjusting medical therapy based on occurrence of different types of activities performed by the patient while automatically rescheduling stimulation programs based on detected patient activity.

A neural stimulation and recording electrode assembly includes a selectively deformable guide tube. The guide tube includes a plurality of sequentially coupled connecting structures, wherein each connecting structure of the plurality of connecting structures has a respective central axis, and wherein at least one of the plurality of connecting structures is selectively deformable relative to the central axis of a sequential connecting structure of the plurality of connecting structures such that the central axis of the selectively deformable connecting structure is angularly oriented relative to the central axis of the sequential connecting structure. The electrode assembly further includes an electrode subassembly having a central axis and a plurality of electrode contacts that are configured for selective radial movement about and between a retracted position and a deployed position, wherein in the deployed position, and relative to the central axis, each electrode contact is spaced radially outwardly from the retracted position.