| Patent application number | Description | Published |
|---|
| 20080294211 | COUPLED MONOPOLAR AND MULTIPOLAR PULSING FOR CONDITIONING AND STIMULATION - A method and neurostimulation system of providing therapy to a patient is provided. A plurality of electrodes are placed in contact with tissue of a patient, a conditioning pulse is conveyed from the plurality of electrodes in one of a monopolar manner and a multipolar manner, and a stimulation pulse is conveyed from the plurality of electrodes in a different one of the monopolar manner and the multipolar manner. As one example, the sub-threshold conditioning pulse may be a depolarizing pulse conveyed from the plurality of electrodes to render a first region of the tissue less excitable to stimulation, and the stimulation pulse may be conveyed from the plurality of electrodes to stimulate a second different region of the tissue. | 11-27-2008 |
| 20080294226 | SHORT DURATION PRE-PULSING TO REDUCE STIMULATION-EVOKED SIDE-EFFECTS - A method and neurostimulation system of providing therapy to a patient is provided. At least one electrode is place in contact with tissue of a patient. A sub-threshold, hyperpolarizing, conditioning pre-pulse (e.g., an anodic pulse) is conveyed from the electrode(s) to render a first region of the tissue (e.g., dorsal root fibers) less excitable to stimulation, and a depolarizing stimulation pulse (e.g., a cathodic pulse) is conveyed from the electrode(s) to stimulate a second different region of the tissue (e.g., dorsal column fibers). The conditioning pre-pulse has a relatively short duration (e.g., less than 200 μs). | 11-27-2008 |
| 20090082835 | Apparatus and Methods For Charging An Implanted Medical Device Power Source - Apparatus and methods for charging an implanted medical device. | 03-26-2009 |
| 20090234427 | SYSTEMS, APPARATUSES, AND METHODS FOR DIFFERENTIATING BETWEEN MULTIPLE LEADS IMPLANTED WITHIN A PATIENT - Systems, apparatuses, and methods for differentiating between multiple leads that are implanted within a patient include a stimulator configured to be implanted at an implant site within the patient and generate electrical stimulation current, a plurality of leads each comprising one or more electrodes configured to deliver the electrical stimulation current at a stimulation site within the patient, and a shuttle assembly having a plurality of receiving ports each configured to receive a proximal portion of one of the leads and guide the leads from the stimulation site to the implant site of the stimulator. The shuttle assembly is configured to enable a user to differentiate between each of the leads after the leads are guided to the implant site of the stimulator. | 09-17-2009 |
| 20090326627 | DEVICES WITH CANNULA AND ELECTRODE LEAD FOR BRAIN STIMULATION AND METHODS OF USE AND MANUFACTURE - A device for brain stimulation includes a cannula configured and arranged for insertion into a brain of a patient; at least one cannula electrode disposed on the cannula; and an electrode lead for insertion into the cannula, the electrode lead comprising at least one stimulating electrode. | 12-31-2009 |
| 20100106204 | SYSTEMS AND METHODS FOR DETECTING A LOSS OF ELECTRICAL CONNECTIVITY BETWEEN COMPONENTS OF IMPLANTABLE MEDICAL LEAD SYSTEMS - A connection monitoring system for an implantable medical lead system includes an implantable lead, a first trial system cable, an external trial system, and a sensor. The lead has a distal end and at least one proximal end. The lead includes a plurality of terminals disposed at each proximal end. The first trial system cable has a distal end and at least one proximal end. The distal end of the first trial system cable is configured and arranged to electrically couple with the lead. The external trial system is configured and arranged to electrically couple with the first trial system cable. The sensor is electrically coupled to the external trial system. The sensor is configured and arranged for detecting a loss of electrical connectivity between the external trial system and the lead when the lead becomes electrically decoupled from the external trial system. | 04-29-2010 |
| 20100106206 | METHOD TO DETECT PROPER LEAD CONNECTION IN AN IMPLANTABLE STIMULATION SYSTEM - An implantable pulse generator or external trial stimulator for coupling to a lead with a distal end and a proximal end, the lead comprising at least one terminal disposed at the proximal end. The implantable pulse generator comprises a connector for receiving the proximal end of the lead, the connector having at least one contact, and a sensor configured and arranged for detecting electrical connectivity between the implantable pulse generator or external trial stimulator and the lead, the sensor comprising at least one sensor contact, the sensor contact being configured and arranged for electrically coupling to a terminal of the lead and at least one of the contacts of the connector when the lead is fully inserted in the connector and thereby detecting electrical connectivity between the implantable pulse generator or external trial stimulator and the lead. | 04-29-2010 |
| 20100137960 | IMPLANTABLE NEUROSTIMULATORS HAVING REDUCED POCKET STIMULATION - Neurostimulators and methods of using neurostimulators are provided. The neurostimulator is implanted within a tissue pocket of a patient, and electrical energy is conveyed from the neurostimulator to stimulate a target tissue site remote from the tissue pocket. The neurostimulator has a case with which one or more electrodes are associated. The electrical energy is returned to the electrode(s) in a manner that prevents, or at least reduces, pocket stimulation that may otherwise occur due to the return of electrical energy to the case of the neurostimulator. | 06-03-2010 |
| 20100137961 | IMPLANTABLE NEUROSTIMULATORS HAVING REDUCED POCKET STIMULATION - Neurostimulators and methods of using neurostimulators are provided. The neurostimulator is implanted within a tissue pocket of a patient, and electrical energy is conveyed from the neurostimulator to stimulate a target tissue site remote from the tissue pocket. The neurostimulator has a case with which one or more electrodes are associated. The electrical energy is returned to the electrode(s) in a manner that prevents, or at least reduces, pocket stimulation that may otherwise occur due to the return of electrical energy to the case of the neurostimulator. | 06-03-2010 |
| 20100137962 | IMPLANTABLE NEUROSTIMULATORS HAVING REDUCED POCKET STIMULATION - Neurostimulators and methods of using neurostimulators are provided. The neurostimulator is implanted within a tissue pocket of a patient, and electrical energy is conveyed from the neurostimulator to stimulate a target tissue site remote from the tissue pocket. The neurostimulator has a case with which one or more electrodes are associated. The electrical energy is returned to the electrode(s) in a manner that prevents, or at least reduces, pocket stimulation that may otherwise occur due to the return of electrical energy to the case of the neurostimulator. | 06-03-2010 |
| 20100228325 | SHORT DURATION PRE-PULSING TO REDUCE STIMULATION-EVOKED SIDE-EFFECTS - A method and neurostimulation system of providing therapy to a patient is provided. At least one electrode is place in contact with tissue of a patient. A sub-threshold, hyperpolarizing, conditioning pre-pulse (e.g., an anodic pulse) is conveyed from the electrode(s) to render a first region of the tissue (e.g., dorsal root fibers) less excitable to stimulation, and a depolarizing stimulation pulse (e.g., a cathodic pulse) is conveyed from the electrode(s) to stimulate a second different region of the tissue (e.g., dorsal column fibers). The conditioning pre-pulse has a relatively short duration (e.g., less than 200 μs). | 09-09-2010 |
| 20100234918 | SYSTEM AND METHOD FOR UNIFORMLY DISPLACING A REGION OF NEURAL STIMULATION - A tissue stimulation system and computer software and method of operating the system is provided. An array of electrodes is placed contact with tissue of a patient (e.g., neural tissue), and electrical current is conveyed within the electrode array, thereby creating a stimulation region in the tissue. Electrical current is shifted between cathodes of the electrode array in incremental steps over a range, thereby causing displacement of the stimulation region at substantially uniform distances over the incremental steps. The electrical current may be shifted between the cathodes in accordance with a sigmoid-like function of a position of the stimulation region. A navigation table containing a series of states and corresponding gradually and non-uniformly changing electrical current values can be accessed, in which case, the electrical current may be shifted between the cathodes by incrementing through the states of the navigation table. | 09-16-2010 |
| 20100268298 | DEEP BRAIN STIMULATION CURRENT STEERING WITH SPLIT ELECTRODES - A device for brain stimulation includes a lead having a longitudinal surface, a proximal end, a distal end and a lead body. The device also includes a plurality of electrodes disposed along the longitudinal surface of the lead near the distal end of the lead. The plurality of electrodes includes a first set of segmented electrodes comprising at least two segmented electrodes disposed around a circumference of the lead at a first longitudinal position along the lead; and a second set of segmented electrodes comprising at least two segmented electrodes disposed around a circumference of the lead at a second longitudinal position along the lead. The device further includes one or more conductors that electrically couple together all of the segmented electrodes of the first set of segmented electrodes. | 10-21-2010 |
| 20100305631 | APPARATUS AND METHOD FOR DETERMINING THE RELATIVE POSITION AND ORIENTATION OF NEUROSTIMULATION LEADS - A method for determining whether the relative position of electrodes used by a neurostimulation system has changed within a patient comprises determining the amplitude of a field potential at each of at least one of the electrodes, determining if a change in each of the determined electric field amplitudes has occurred, and analyzing the change in each of the determined electric field amplitudes to determine whether a change in the relative position of the electrodes has occurred. Another method comprises measuring a first monopolar impedance between a first electrode and a reference electrode, measuring a second monopolar impedance between second electrode and the reference electrode, measuring a bipolar impedance between the first and second electrodes, and estimating an amplitude of a field potential at the second electrode based on the first and second monopolar impedances and the bipolar impedance. | 12-02-2010 |
| 20110022122 | SYSTEM AND METHOD FOR COMPUTATIONALLY DETERMINING MIGRATION OF NEUROSTIMULATION LEADS - A tissue stimulation system and computer software and method of monitoring a neurostimulation lead having a plurality of electrodes implanted within a patient (e.g., adjacent the spinal cord) is provided. Neurostimulation lead models are provided, each of which includes estimated electrical parameter data (e.g., electrical field potential data) corresponding to a predetermined position of the neurostimulation lead. Electrical energy is transmitted to or from the electrodes, and electrical parameter data (e.g., electrical field potential data) is measured in response to the transmitted electrical energy. The measured electrical parameter data is compared with the estimated electrical parameter data of each of the neurostimulation lead models, and a position of the neurostimulation lead is determined based on the comparison. | 01-27-2011 |
| 20110093044 | SYSTEM AND METHOD FOR MODELING ELECTRODE MORPHOLOGIES - A system for a neurostimulation device comprises a user input device configured for receiving an electrode morphology having at least one electrode, memory storing at least one basis electrode model, and at least one processor configured for modeling at least one electrode by recalling the at least one basis electrode model from the memory, and using the recalled at least one basis electrode model multiple times to construct a model of the at least one electrode. | 04-21-2011 |
| 20110106215 | SYSTEM AND METHOD FOR MAPPING ARBITRARY ELECTRIC FIELDS TO PRE-EXISTING LEAD ELECTRODES - A method and system for stimulating tissue using a plurality of electrodes is provided. Desired electrical parameter (e.g., field potential) values are determined at a plurality of spatial points. A plurality of constituent current sources is selected at the locations of the electrodes. The relative strengths of the constituent current sources that, when combined, result in estimated electrical parameter (e.g., field potential)|values at the spatial points that best matches the desired electrical parameter values at the spatial points are determined. The polarity and percentage of electrical current to be associated with each of the electrodes is selected based on the determined strengths of the constituent current sources. Electrical current is conveyed through the plurality of electrodes in accordance with the selected electrical current magnitudes to stimulate the tissue. | 05-05-2011 |
