Abstract: An implantable, substantially isodiametric, low resistance implantable lead having at least one electrode positioned in a stimulation/sensing portion of the lead as well as a method of manufacturing the same. At least the stimulation/sensing portion is unitized through partially surrounding and supporting insulation and conductive element(s) of the stimulation/sensing portion with a fused matrix of material having mechanical properties consistent with a body of the lead.

Abstract: In one embodiment, a pulse generator for generating electrical stimulation for delivery to a patient, comprises: a hermetically sealed housing containing pulse generating circuitry; a header coupled to the housing for receiving one or more stimulation leads, wherein feedthrough wires are provided to conduct electrical pulses from the pulse generating circuitry to the header; the header comprising a plurality of connectors for electrically connecting to each terminal of the one or more stimulation leads, wherein an inductive winding is disposed around or adjacent to each of the connector structures and is electrically connected between the respective connector structure and a corresponding feedthrough wire to limit MRI induced heating of a respective electrode of the one or more stimulation leads.

Abstract: The present invention relates to a method of identifying a target such as within the subgenual area by measuring neuronal activity in response to a stimulus. Once the target is identified, it can be stimulated to treat a neurological disorder, such as a mood disorder or an anxiety disorder.

Abstract: In one embodiment, a kit, for securing a lead or cannula within a burr hole, comprises: a base structure to be positioned immediately adjacent to or partially within the burr hole; a lead securing member for securing the lead within the burr hole, the lead securing member comprising a first arm structure and a second arm structure, at least one spring loaded structure adapted to exert a force to bring the first arm structure and the second arm structure together; and a positioning tool having a distal end adapted to be inserted within the lead securing member; wherein when the distal end of the positioning tool is positioned within the lead securing member, the distal end holds the first and second arm structures a sufficient distance apart to receive a lead or a cannula between the first and second arm structures.

Abstract: Disclosed are systems and methods which provide voltage conversion in increments less than integer multiples of a power supply (e.g., battery) voltage. A representative embodiment provides power supply voltage multipliers in a binary ladder distribution to provide a desired number of output voltage steps using a relatively uncomplicated circuit design. By using different sources in various combinations and/or by “stacking” different sources in various ways, the voltage multiplier circuit may be used to provide desired voltages. In order to minimize the number of components used in a voltage converter of an embodiment, a capacitive voltage converter circuit uses one or more storage capacitors in place of pump capacitors in a voltage generation cycle. Also, certain embodiments do not operate to generate an output voltage until the time that voltage is needed.

Abstract: There is disclosed various embodiments of an implantable anchor for anchoring a medical lead within a patient. The implantable anchor includes a body having at least one lumen for receiving a medical lead, a cam integrated with the body and rotatable to extend into the lumen for engaging, compressing and twisting the medical lead to inhibit the movement of the lead with respect to the anchor. The body of the anchor may include at least one slot, sized and positioned to receive a portion of the lead to further facilitate the inhibition of the movement of the lead. The cam may include a handle for facilitating the rotation and locking of the cam.

Abstract: A method for treatment of obesity or other disorders by electrical activation or inhibition of nerves is disclosed. This activation or inhibition can be accomplished by stimulating a nerve using an electrode. The method further comprises performing a surgical procedure and/or administering a weight loss drug.

Abstract: An implantable medical device that includes a header a cavity or connector bore that extends from an opening at a first end of the header towards a second end of the header. The cavity is configured to receive a first end of a stimulation lead. The header includes a lead insertion indicator positioned at the second end of the cavity for engaging with the stimulation upon complete insertion into the header. The lead insertion indicator is operable between a first operating state and a second operating state, such that when the stimulation lead is not engaged with the lead insertion indicator, the lead insertion indicator operates in the first operating state, and when the stimulation lead properly engages the lead insertion indicator, the lead insertion indicator operates in the second operating state. The lead insertion indicator generates a signal that indicates the corresponding operating state.

Abstract: The present invention relates to a method of identifying a region of the brain by measuring neuronal firing and/or local field potentials by recording discharges from at least one implanted electrode and analyzing the recording of the discharges within the beta frequency band range to determine an area of beta oscillatory activity. Once the region of the brain is identified, this region may be stimulated to disrupt the beta oscillatory activity thereby treating a movement disorder.

Abstract: A method of fabricating a stimulation lead by supplying a lead body with a plurality wire conductors extending the length of the lead body and being within insulative material therein; providing a plurality of terminals and electrodes on the ends of the lead body, wherein the plurality of terminals and electrodes are electrically coupled, wherein the providing comprises: (i) positioning a conductive band about the lead body that is adapted to be clasped about the lead body; (ii) positioning a conductor wire between an exterior surface of the first end and an interior surface of the second end of the conductive band; (iii) closing overlapping ends of the conductive band about the conductor wire; and (iv) welding the ends to seal the conductive band about the lead body.

Abstract: In one embodiment, a method, of fabricating a stimulation lead for stimulating tissue of a patient, comprises: providing a lead body, the lead body comprising a plurality of conductors embedded within insulating material; providing a plurality of terminals; electrically coupling the plurality of terminals with the plurality of conductors; providing a plurality of electrodes, the plurality of electrodes comprising a plurality of substantially continuous longitudinal trenches on a surface of the electrodes, the electrodes comprising areas of reflow material forming microstructures substantially continuously along walls of the longitudinal trenches; and electrically coupling the plurality of electrodes with the plurality of conductors.

Abstract: In one embodiment, a paddle-style lead for implantation in the epidural space, the paddle-style lead comprising: a paddle structure that comprises a frame of rigid material, the frame comprising first, second, and third longitudinal members, a distal linking portion that is mechanically coupled to the first, second, and third longitudinal members, and a proximal linking portion that is mechanically coupled to the first, second, and third longitudinal members; wherein a respective plurality of electrodes are provided for each of the first, second, and third longitudinal members, each plurality of electrodes being electrically coupled to conductors of a lead body; wherein the distal and proximal linking portions are adapted to permit compression of the first and third longitudinal members toward each other and to permit the second longitudinal member to move out of plane relative to the first and third longitudinal members when a compressive force is applied to the paddle.

Abstract: The present application involves a method and a system for using electrical stimulation and/or chemical stimulation to treat depression. More particularly, the method comprises surgically implanting an electrical stimulation lead and/or catheter that is in communication with a predetermined site which is coupled to a signal generator and/or infusion pump that release either an electrical signal and/or a pharmaceutical resulting in stimulation of the predetermined site thereby treating the mood and/or anxiety.

Abstract: The present disclosure is directed generally to techniques for selecting signal delivery sites and other signal delivery parameters for treating depression and other neurological disorders, and associated systems and methods. A method in accordance with a particular embodiment includes obtaining first imaging information corresponding to a first region of a patient's brain, the first imaging information being based at least in part on functional characteristics of the first region. The method further includes obtaining second imaging information corresponding to a second region of the patient's brain, the second region being a subset of the first region, the second imaging information being based at least in part on functional or structural characteristics of the second region. A target neural population is then selected based at least in part on the second imaging information. The method still further includes applying an electromagnetic signal to the target neural population to improve a patient function.

Abstract: In one embodiment, an apparatus comprises: a base structure adapted to be inserted within the burr hole; a lead securing member for securing the lead, the lead securing member comprising a first arm structure and a second arm structure, at least one spring loaded structure adapted to exert a force to bring the first arm structure and the second arm structure together; and a positioning tool having a distal end adapted to be inserted within the lead securing member. When the positioning tool is positioned within the lead securing member, the distal end holds the first and second arm structures a sufficient distance apart to receive a lead between the first and second arm structures; wherein the positioning tool comprises a control structure at a proximal end that, when engaged, causes the distal end of the positioning tool to be released from between the first and second arm structures.

Abstract: In one embodiment, a process, for fabricating a medical lead for stimulation of tissue of a patient, comprises: providing a plurality of wires; increasing an exterior surface area of each wire of the plurality of wires; arranging the plurality of wires angularly around a longitudinal axis; extruding polymer material of the plurality of wires; forming a lead body with a proximal end and a distal end after performing the extruding; and forming a plurality of terminals at a proximal end of the lead body; forming a plurality of segmented electrodes at a distal end of the lead body.

Abstract: In one embodiment, a neurostimulation lead comprises an elongated body of insulative material, comprising a first end portion and a second end portion; a plurality of terminals longitudinally positioned along the first end portion; a plurality of electrodes longitudinally positioned along the second end portion; a plurality of conductors electrically coupling the plurality of electrodes to the plurality of terminals; a flexible metal longitudinal stiffener positioned within the elongated body wherein the stiffener has a plurality of longitudinal zones and each zone has a different column strength, the column strength of one or more zones of the plurality of longitudinal zones being defined by cuts or gaps in the stiffener, the stiffener causing the neurostimulation lead to exhibit a greatest amount of column strength adjacent to one end portion of the elongated body and to transition to a lower column strength toward a medial portion of the elongated body.

Abstract: According to one aspect, a stimulation system is provided for electrically stimulating a predetermined site to treat a fragile bone disorder or condition. The system includes an electrical stimulation lead adapted for implantation into a subcutaneous area in communication with a predetermined site, wherein the site is neuronal tissue that is associated with C2/C3 dermatome area. The stimulation lead includes one or more stimulation electrodes adapted to be positioned in the predetermined site. The system also includes a stimulation source that generates the stimulation pulses for transmission to the one or more stimulation electrodes of the stimulation lead to deliver the stimulation pulses to the predetermined site to treat a fragile bone disorder or condition.

Abstract: The present description relates to cranial nerve stimulation to treat a neurological disorder. More particularly, and not by way of limitation, the present invention is directed to a system and method for stimulating a cranial nerve to treat a neurological disorder, such as tinnitus or an anxiety disorder.

Abstract: In one embodiment, a method of electrically stimulating neural tissue of a patient, comprises: generating, by an implantable pulse generator, one or more electrical pulses; applying the one or more electrical pulses to neural tissue of a patient using one or more electrodes of one or more stimulation leads; concurrently with the generating, providing a voltage waveform or signal by the implantable pulse generator; and concurrently with the applying, electrically coupling one or more field effect electrodes of the one or more stimulation leads to the voltage waveform or signal to generate a localized electric field within tissue proximate to the one or more electrodes used to apply the one or more electrical pulses.