Abstract: A nerve stimulation lead has a distal end, a proximal end, and a longitudinal length. The nerve stimulation lead includes a plurality of electrodes disposed at the distal end, a plurality of terminals disposed at the proximal end, and a plurality of conductive wires electrically coupling the plurality of electrodes electrically to the plurality of terminals. The nerve stimulation lead also includes at least one anchoring unit disposed on the nerve stimulation lead. The at least one anchoring unit is configured and arranged for anchoring the nerve stimulation lead against a bony structure.

Abstract: Exemplary systems include a stimulator configured to be implanted within a patient, the stimulator having a body defined by at least one side surface disposed in between distal and proximal end surfaces, and a connector assembly configured to be coupled to the stimulator and extend parallel to the at least one side surface of the stimulator. The connector assembly is further configured to facilitate removable coupling of a lead having one or more electrodes disposed thereon to the stimulator.

Abstract: An improved external charger for a battery in an implantable medical device (implant), and technique for charging the battery using such improved external charger, is disclosed. In one example, simulation data is used to model the power dissipation of the charging circuitry in the implant at varying levels of implant power. A power dissipation limit is chosen to constrain the charging circuitry from producing an inordinate amount of heat to the tissue surrounding the implant, and duty cycles are determined for the various levels of input intensities to ensure that the power limit is not exceeded. A maximum simulated average battery current determines the optimal (i.e., quickest) battery charging current, and at least an optimal value for a parameter indicative of that current, for example, the voltage across the battery charging circuitry, is determined and stored in the external charger.

Abstract: A burr hole plug comprises a plug base configured for being mounted around a burr hole. The plug base includes an aperture through which an elongated medical device exiting the burr hole may pass. The burr hole plug further comprises a retainer configured for being mounted within the aperture of the plug base. The retainer further includes first and second slidable clamping mechanisms configured for securing the medical devices therebetween within the aperture of the plug base. A method comprises introducing the medical device through the burr hole, mounting a plug base around the burr hole, such that the medical device extends through the plug base aperture, mounting the retainer within the aperture of the plug base, and sliding the first and second clamping mechanisms secure the medical device therebetween.

Abstract: An implantable stimulation device includes a device body; at least one set of partitioned electrodes disposed on a portion of the device body and configured and arranged for application of electrical stimulation to adjacent tissue; and insulating material separating the partitioned electrodes from each other. Each set of partitioned electrodes includes a plurality of partitioned electrodes disposed around a circumference of the device body. The implantable stimulation device can be configured and arranged so that each of the partitioned electrodes is independently programmable.

Abstract: Apparatus and methods for charging an implanted medical device.

Abstract: Exemplary systems include a stimulator configured to be implanted within a patient, the stimulator having a body defined by at least one side surface disposed in between distal and proximal end surfaces, and a connector assembly configured to be coupled to the stimulator and extend parallel to the at least one side surface of the stimulator. The connector assembly is further configured to facilitate removable coupling of a lead having one or more electrodes disposed thereon to the stimulator.

Abstract: An improved external charger for a battery in an implantable medical device (implant), and technique for charging batteries in multiple implants using such improved external charger, is disclosed. During charging, values for a parameter measured in the implants are reported from the implants to the external charger. The external charger infers from the magnitudes of the parameters which of the implants has the highest and lowest coupling to the external charger, and so designates those implants as “hot” and “cold.” The intensity of the magnetic charging field is optimized for the cold implant consistent with the simulation to ensure that that the cold implant is charged with a maximum (fastest) battery charging current. The duty cycle of the magnetic charging field is also optimized for the hot implant consistent with the simulation to ensure that the hot implant does not exceed the power dissipation limit.

Abstract: Methods and systems of treating a patient with pancreatitis pain include providing a stimulator, configuring one or more stimulation parameters to treat pancreatitis pain, programming the stimulator with the one or more stimulation parameters, generating a stimulus configured to treat pancreatitis pain with the stimulator in accordance with the one or more stimulation parameters, and applying the stimulus with the stimulator to one or more stimulation sites in accordance with the one or more stimulation parameters.

Abstract: A system and method for applying stimulation to a target stimulation site within a patient, while avoiding undesirable eye movement side effects of the stimulation, are provided. The method includes determining whether eye movement, sensed by internal or external electrodes, is a side effect of a conveyed electrical stimulus. If the eye movement is a side effect, the electrical current distribution of the stimulus is modified in order to steer a locus of the electrical stimulus from one tissue region of the patient to another different tissue region of the patient, thereby mitigating the eye movement side effects. For example, the locus of the electrical stimulus may be steered away from the oculomotor nerve. Eye movement side effects of DBS treatment may include apraxia of lid opening, downward movement and adduction of only one eyeball, and/or continuous deviation of both eyeballs.

Abstract: One embodiment is an implantable lead including a lead body having a proximal end and a distal end; multiple electrodes disposed along the distal end of the lead body; multiple terminal contacts disposed along the proximal end of the lead body; multiple stimulation conductors extending along the lead body and electrically coupling the electrodes to the terminal contacts; at least one diversionary terminal contact disposed along the proximal end of the lead body; and at least one diversionary conductor extending at least partially along the length of the lead body and coupled to the at least one diversionary terminal contact and not coupled to any of the electrodes. The at least one diversionary conductor is configured and arranged to capacitively couple to the stimulation conductors.

Abstract: Methods for treating seizures caused by brain stimulation include providing a stimulator, programming the stimulator with one or more stimulation parameters configured to treat a medical condition, applying at least one stimulus with the stimulator to a stimulation site within the brain of a patient in accordance with the one or more stimulation parameters, and monitoring the patient for a seizure caused by the at least one stimulus.

Abstract: An implantable control module for an electrical stimulation system includes a header coupled a sealed body. The header includes at least one connector assembly. The control module also includes a conductive shield disposed over at least a portion of the connector assembly or connector assemblies of the header. The conductive shield is provided to hinder generation of current in the header or in a portion of a lead received in the header in response to application of an external radiofrequency (RF) or magnetic field. A similar shield can also be used to shield a connector assembly disposed on the end of a lead extension or any other component of the electrical stimulation system.

Abstract: Disclosed is a remote controller for an implantable medical device having stored contraindication information, which includes information which a patient or clinician might wish to review when assessing the compatibility of a given therapeutic or diagnostic technique or activity with the patient's implant. The stored contraindication information is available through a display of the remote controller or via a wired, wireless, or portable drive connection with an external device. By storing contraindication information with the implant's remote controller, patient and clinician can more easily determine the safety of a particular therapeutic or diagnostic technique or physical activity with the patient's implant, perhaps without the need to contact the manufacturer's service representative.

Abstract: Miniature implantable stimulators (i.e., microstimulators) are capable of producing unidirectionally propagating action potentials (UPAPs). The methods and configurations described may, for instance, arrest action potentials traveling in one direction, arrest action potentials of small diameters nerve fibers, arrest action potentials of large diameter nerve fibers. These methods and systems may limit side effects of bidirectional and/or less targeted stimulation.

Abstract: Disclosed are charging algorithms implementable in an external charger for controlling the charging of both an external battery in the external charger and an implant battery in an implantable medical device. Because full-powered simultaneous charging of both batteries can generate excessive heat in the external charger, the various charging algorithms are designed to ensure that both batteries are ultimately charged, but in a manner considerate of heat generation. In some embodiments, the charging algorithms prevent simultaneous charging of both batteries by arbitrating which battery is given charging precedence at a given point in time. In other embodiments, the charging algorithms allow for simultaneous charging of both batteries, but with at least one of the batteries being only weakly charged at low power levels. In other embodiments, the temperature generated in the external charger is monitored and used to control the charging algorithm.

Abstract: Apparatus and methods for charging an implanted medical device.

Abstract: A neuromodulation system and method of providing therapy to a patient. A plurality of individual electrical pulse trains is generated at a respective plurality of individual pulse rates. The plurality of individual electrical pulse trains are concurrently respectively from a plurality of electrodes to a common electrode via tissue of the patient, thereby creating a combined electrical pulse train having an average pulse rate equal to or greater than 1 KHz.

Abstract: A nerve stimulation lead has a distal end, a proximal end, and a longitudinal length. The nerve stimulation lead includes a plurality of electrodes disposed at the distal end, a plurality of terminals disposed at the proximal end, and a plurality of conductive wires electrically coupling the plurality of electrodes electrically to the plurality of terminals. The nerve stimulation lead also includes at least one anchoring unit disposed on the nerve stimulation lead. The at least one anchoring unit is configured and arranged for anchoring the nerve stimulation lead against a bony structure.

Abstract: A neurostimulation device capable of being placed between a stimulation state and an EMI protection state. The neurostimulation device comprises a plurality of electrical terminals configured for being respectively coupled to a plurality of stimulation electrodes, stimulation output circuitry configured for being selectively activated during the stimulation state to output a plurality of stimulation pulses to the plurality of electrical terminals, electromagnetic protection circuitry configured for being selectively activated during the EMI protection state to prevent at least a portion of the electrical current induced on at least one of the electrical terminals by an electromagnetic field entering the stimulation output circuitry, and a controller configured for automatically defaulting the neurostimulation device to the EMI protection state.