Abstract: In some embodiments, a paddle lead is implanted within a patient such that the electrodes are positioned within the cervical or thoracic spinal levels. An electrode combination on a first row of electrodes can be determined that is effective for a first pain location with minimal effects on other regions of the body. The first pain location can be addressed by stimulating a first dorsal column fiber due to the relatively fine electrical field resolution achievable by the multiple columns. Then, another electrode combination on a second row of electrodes can be determined for a second pain location with minimal effects on other regions. The second pain location could be addressed by stimulating a second dorsal column fiber. After the determination of the appropriate electrodes for stimulation, the patient's IPG can be programmed to deliver pulses using the first and second rows according to the determined electrode combinations.

Abstract: In one embodiment, a method of operating an implantable pulse generator comprises: providing power to a voltage converter at a first voltage level; outputting a second voltage level by the voltage converter, the second voltage level being a variable voltage level that is controlled by a control signal provided to the voltage converter, the second voltage level being provided to pulse generating circuitry of the implantable pulse generator, the second voltage level being selectable from a plurality of voltages including non-integer multiples of the first voltage level; generating pulses by the pulse generating circuitry, the pulse generating circuitry including current control circuitry for controlling the pulses to cause the pulses to provide substantially constant current to tissue of the patient; and applying at least two different control signals to the voltage converter during individual pulses to provide successively increasing voltages to the pulse generating circuitry during a respective pulse.

Abstract: In one embodiment, a method for defining a stimulation program for electrical stimulation of a patient, the method comprising: providing a single screen user interface that comprises a first plurality of controls and a second plurality of controls, the first plurality of controls allowing selection of multiple stimulation parameters for a plurality of stimulation sets, the second plurality of controls allowing selection of multiple stimulation parameters defining burst stimulation and tonic stimulation; receiving user input in one or more of the second plurality of controls; and automatically modifying parameters for one or more stimulation sets in response to receiving the user input in one or more of the second plurality of controls and modifying values displayed in one or more controls of the first plurality of controls according to the modified parameters, the modified parameters reflecting a stimulation program that includes an interleaved pattern of burst stimulation and tonic stimulation for delivery t

Abstract: In one embodiment, a method of programming an IPG comprises providing one or several GUI screens on the programmer device, the GUI screens comprising a master amplitude GUI control for controlling amplitudes for stimsets of a stimulation program and one or several balancing GUI controls for controlling amplitudes of each stimset of the stimulation program; communicating one or several commands from the programmer device to the IPG to change the amplitude of all stimsets of the stimulation program in response to manipulation of the master amplitude GUI control, wherein the amplitude of each stimulation set is automatically calculated by a level selected through the master amplitude GUI control and one or several calibration parameters for the respective stimulation set; and automatically recalculating the one or several calibration parameters for a respective stimulation set in response to manipulation of one of the balancing GUI controls and storing the recalculated calibration parameters.

Abstract: In some embodiments, a paddle lead is implanted within a patient such that the electrodes are positioned within the cervical or thoracic spinal levels. An electrode combination on a first row of electrodes can be determined that is effective for a first pain location with minimal effects on other regions of the body. The first pain location can be addressed by stimulating a first dorsal column fiber due to the relatively fine electrical field resolution achievable by the multiple columns. Then, another electrode combination on a second row of electrodes can be determined for a second pain location with minimal effects on other regions. The second pain location could be addressed by stimulating a second dorsal column fiber. After the determination of the appropriate electrodes for stimulation, the patient's IPG can be programmed to deliver pulses using the first and second rows according to the determined electrode combinations.

Abstract: In some embodiments, a paddle lead is implanted within a patient such that the electrodes are positioned within the cervical or thoracic spinal levels. An electrode combination on a first row of electrodes can be determined that is effective for a first pain location with minimal effects on other regions of the body. The first pain location can be addressed by stimulating a first dorsal column fiber due to the relatively fine electrical field resolution achievable by the multiple columns. Then, another electrode combination on a second row of electrodes can be determined for a second pain location with minimal effects on other regions. The second pain location could be addressed by stimulating a second dorsal column fiber. After the determination of the appropriate electrodes for stimulation, the patient's IPG can be programmed to deliver pulses using the first and second rows according to the determined electrode combinations.

Abstract: The present invention relates to a multi-column paddle structure and its uses thereof to provide neuromodulation therapy to a patient.

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 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: In one embodiment, a method of programming an IPG comprises providing one or several GUI screens on the programmer device, the GUI screens comprising a master amplitude GUI control for controlling amplitudes for stimsets of a stimulation program and one or several balancing GUI controls for controlling amplitudes of each stimset of the stimulation program; communicating one or several commands from the programmer device to the IPG to change the amplitude of all stimsets of the stimulation program in response to manipulation of the master amplitude GUI control, wherein the amplitude of each stimulation set is automatically calculated by a level selected through the master amplitude GUI control and one or several calibration parameters for the respective stimulation set; and automatically recalculating the one or several calibration parameters for a respective stimulation set in response to manipulation of one of the balancing GUI controls and storing the recalculated calibration parameters.

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: The present invention relates to a percutaneous insertion-capable lead, wherein insertion made through a percutaneous insertion structure. For one embodiment of such lead, the electrode-supporting stimulation portion of the lead includes at least one waisted region, relative to a transverse dimension of the lead, to facilitate lead steerability.

Abstract: In one embodiment, there is disclosed a lead locking mechanism for use in a header component of an implantable pulse generator. In certain embodiments, the lead locking mechanism comprises a first locking member positioned to engage a surface of at least two leads; a second locking member positioned to also engage a surface of at least two leads, and a coupling member coupling the first locking member to the second locking member.

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 some embodiments, a paddle lead is implanted within a patient such that the electrodes are positioned within the cervical or thoracic spinal levels. An electrode combination on a first row of electrodes can be determined that is effective for a first pain location with minimal effects on other regions of the body. The first pain location can be addressed by stimulating a first dorsal column fiber due to the relatively fine electrical field resolution achievable by the multiple columns. Then, another electrode combination on a second row of electrodes can be determined for a second pain location with minimal effects on other regions. The second pain location could be addressed by stimulating a second dorsal column fiber. After the determination of the appropriate electrodes for stimulation, the patient's IPG can be programmed to deliver pulses using the first and second rows according to the determined electrode combinations.

Abstract: The present invention relates to a percutaneous insertion-capable lead, wherein insertion made through a percutaneous insertion structure. For one embodiment of such lead, the electrode-supporting stimulation portion of the lead includes at least one waisted region, relative to a transverse dimension of the lead, to facilitate lead steerability.

Abstract: In one embodiment, a method for defining a stimulation program for electrical stimulation of a patient, the method comprising: providing a single screen user interface that comprises a first plurality of controls and a second plurality of controls, the first plurality of controls allowing selection of multiple stimulation parameters for a plurality of stimulation sets, the second plurality of controls allowing selection of multiple stimulation parameters defining burst stimulation and tonic stimulation; receiving user input in one or more of the second plurality of controls; and automatically modifying parameters for one or more stimulation sets in response to receiving the user input in one or more of the second plurality of controls and modifying values displayed in one or more controls of the first plurality of controls according to the modified parameters, the modified parameters reflecting a stimulation program that includes an interleaved pattern of burst stimulation and tonic stimulation for delivery t

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: 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: 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.