Abstract: In one embodiment, a method, of operating an IPG, comprises: generating a variable anode voltage by first circuitry to drive current during pulse generation, the first circuitry being programmable to generate the anode voltage from a plurality of voltages in response to a control signal; providing the anode voltage to a first circuit node; operating a transistor to control current flow between the first circuit node and an output of the IPG, wherein the transistor possesses a gate-to-source breakdown voltage; generating a first supply signal that is maintained at a voltage level equal to the anode voltage plus or minus a predetermined amount; and selectively applying the first supply signal and a second supply signal to a gate of the transistor to connect or disconnect the first circuit node in a circuit path with the output of the IPG.

Abstract: In one embodiment, a method, for estimating electrode resistance values, comprises: calculating an aggregate resistance value for each electrode in a group of electrodes of an implantable stimulation lead of the electrical stimulation system, wherein the calculating, for each electrode, comprises: (i) setting a respective electrode in the group of electrodes as an anode; (ii) setting electrodes in the group of electrodes other than the respective electrodes as cathodes; (iii) applying a predetermined electrical signal through the group of the electrodes using a pulse generator of the electrical stimulation system; (iv) measuring current flow or voltage resulting from application of the predetermined electrical signal through the group of the electrodes; (v) calculating the aggregate resistance value for the respective electrode in response to the measuring; calculating an individual resistance value for each electrode of the group of electrodes using the set of aggregate resistance values for the group of ele

Abstract: A lead, method of manufacturing same, and system for stimulation is provided. The lead includes an insulative member or layer that masks a portion of the electrode(s) to effectively generate a directional lead that focuses or directs the stimulation to desired location(s). In another embodiment, the lead further includes a marking system to allow a clinician to orient the directional lead, as desired, while the lead is within a body.

Abstract: In one embodiment, a percutaneous stimulation lead for applying electrically stimulation pulses to tissue of the patient comprises: a plurality of electrode assemblies electrically coupled to a plurality of terminals through a plurality of conductors of the stimulation lead, wherein each electrode assembly is disposed in an annular manner around the lead body and each electrode assembly comprises (i) an electrode adapted to deliver electrical stimulation to tissue of a patient, (ii) an interior conductive layer, and (iii) a dielectric layer disposed between the electrode and the interior conductive layer; the electrode and interior conductive layer being capacitively coupled, the dielectric layer further comprising an inductor, the inductor being electrically connected to one of the plurality of conductors through the interior conductive layer, and the inductor being electrically coupled to the electrode.

Abstract: According to one aspect, a stimulation system is provided for electrically stimulating a predetermined site to treat a neurological 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, or stimulating cervical nerve roots and/or stimulating cranial nerves and/or stimulating any area associated with the occipital 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 neurological disorder or condition.

Abstract: Embodiments herein include an external system and method to detect an implanted lead coupled to an implanted neurostimulation device (INSD). The system and method comprise a handheld probe having electrodes configured to be positioned external to a surface of a patient and proximate to a region of the patient having the implanted lead for an implanted INSD. The electrodes are configured to measure a stimulation output from the implanted lead of the INSD. The system and method include a controller coupled to the electrodes to receive measured signals from the electrodes. The measured signals represent the stimulation output of the INSD. The controller processes the measured signals to obtain lead information. The system includes a user interface to present the lead information to a user. The lead information is indicative of at least one of an operation of the lead and a position of the lead.

Abstract: In one embodiment, an implantable pulse generator for electrically stimulating a patient comprises: a metallic housing enclosing pulse generating circuitry; a header mechanically coupled to the metallic housing, the header adapted to seal terminals of one or more stimulation leads within the header and to provide electrical connections for the terminals; the header comprising an inner compliant component for holding a plurality of electrical connectors, the plurality of electrical connectors electrically coupled to the pulse generating circuitry through feedthrough conductors, wherein the plurality of electrical connectors are held in place in recesses within the compliant inner component, the header further comprising an outer shield component adapted to resist punctures, the outer shield component fitting over at least a portion of the inner compliant component.

Abstract: In one embodiment, a method of fabricating a stimulation lead for stimulation of tissue of a patient, the method comprises: providing a plurality of cables, wherein each of the cables comprises a plurality of wires twisted about a core support and disposed within an outer sheath, wherein each of the plurality of wires comprises a coating of insulative material to electrically isolate each wire from each other wire within the respective cable, each of the plurality of wires being disposed in a single layer circumferentially about a central axis of the respective cable; wrapping the plurality of cables about a central core in a helical manner to form a cable assembly.

Abstract: Systems and methods for providing targeted neural stimulation therapy to address neurological disorders, including neuropsychiatric and neuropsychological disorders are disclosed. A method for treating a patient's neurological disorder in accordance with a particular embodiment includes, in a patient identified as having at least one of a neuropsychological disorder and a neuropsychiatric disorder, implanting at least one stimulation electrode within the patient's skull cavity, and outside a cortical surface of the patient's brain. The electrode is implanted at a location in a range of about 15 mm to about 35 mm anterior to a precentral sulcus reference point that is positioned at the precentral sulcus and at the patient's middle frontal gyrus. The method can further include treating the patient's disorder by applying electrical stimulation to the patient via the at least one stimulation electrode.

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: In one embodiment, a lead extension comprises: a lead body; a plurality of conductors disposed within the lead body; a plurality of terminal contacts on a proximal end of the lead body, wherein the plurality of terminal contacts are electrically coupled to the plurality of conductors; and a housing structure disposed at a distal end of the lead body, the housing structure enclosing a plurality of electrical connectors for making electrical contact with terminal contacts of a stimulation lead, wherein the plurality of electrical connectors are electrically coupled to the plurality of conductors; the housing structure comprising an outer body of a first material and an inner reinforcing structure of a second material, wherein the first material is a relatively pliable biocompatible polymer material and the second material is a relatively rigid material, the reinforcing structure holding the plurality of electrical connectors in a relatively fixed arrangement.

Abstract: In one embodiment, a method for the controlling of the stimulation pulses being delivered via electrodes to a patient during the programming of a pulse generator using a controller device and selecting of a minimum amplitude that corresponds to the minimum amplitude for which the patient can detect stimulation; selecting an electrode combination defined in the controller device; setting the stimulation amplitude; making a determination of the amplitude for the stimulation pulses is greater than the perception amplitude, and if so, changing the amplitude of the stimulation pulses to be less than or equal to the perception amplitude; and if not or subsequent to the changing of the amplitude, changing the selected one of a plurality of electrode combinations to a different combination.

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: Electromagnetic signal delivery for tissue affected by neuronal dysfunction, degradation, damage, and/or necrosis, and associated systems and methods are disclosed. A method in accordance with one embodiment of the invention includes identifying an affected region, with the affected region including neuronal tissue that, at least during a pre-dysfunctional period, was in neural communication with neuronal tissue in a dysfunctional region. The affected tissue can be functionally adversely affected by neuronal dysfunction in the dysfunctional region. The method can further include applying electromagnetic signals to the neuronal tissue in the affected region. For example, the electromagnetic signals can be applied to a hypo-active neural region that is not physically damaged, and has been identified as likely to recover at least in part as a result of electromagnetic signals. Signals can be applied at sub-threshold levels to cortical and/or subcortical regions.

Abstract: There is disclosed various embodiments of an implantable anchor for permanently anchoring a medical lead or catheter. For instance, there is disclosed an implantable anchor including a body having a longitudinal lumen defined therein, wherein the longitudinal lumen is sized to accept a portion of the medical lead or catheter, a bending mechanism coupled to the body for bending the lead to a predetermined angle within the body, and a retaining mechanism for maintaining the predetermined angle of the bent lead within the body.

Abstract: In one aspect, an apparatus is provided for securing an electrical stimulation lead in position in a person's brain. The apparatus includes a flexible disc comprising a substantially radial slot adapted to secure the lead in position within the brain after implantation. The slot is adapted to elastically expand as the lead is inserted into the slot and is also adapted to elastically contract on the lead to secure the lead in position within the brain after implantation. The apparatus further includes a ring adapted to seat within a burr hole formed in the person's skull. The ring comprises a channel adapted to receive and secure the flexible disc.

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 a cavity for receiving a medical lead, and a separate, removable key for insertion into the cavity. The key, upon insertion into the cavity, engages and locks the medical lead into place and prevents the movement of the medical lead with respect to the anchor.

Abstract: A method of fabricating a stimulation lead comprises: providing a central insulator member; helically wrapping a plurality of conductors about the member, by arranging the plurality of conductor wires in groups with an inter-group spacing that is larger than an inter-conductor spacing within each group; providing an outer insulator layer to form an intermediate lead body assembly; forming a lead body by heating polymer material of the intermediate lead body assembly to cause insulative material of the lead body to form a solid, fused cylindrical body about the plurality of conductors, which comprise a first conductor, a last conductor, and inner conductors between the first and last conductor, wherein the first and last conductor comprise respective helix diameters that are smaller than the helix diameters of the inner conductors; and forming a plurality of electrodes and terminals on the lead body that are electrically connected through the plurality of conductors.

Abstract: A paddle lead includes a plurality of electrodes configured in at least three rows of three electrodes with the second, intermediate row operable to provide anode guarding. The paddle lead further includes a plurality of grooves disposed on a surface opposite the electrodes to facilitate the insertion of the paddle lead within a patient by inhibiting the veering of the paddle lead to one side or the other of the dorsal column as the paddle lead is advanced along the dorsal column midline during implantation.