Abstract: A system and method for applying electrical stimulation or drug infusion to nervous tissue of a patient to treat epilepsy, movement disorders, and other indications uses at least one implantable system control unit (SCU) (110), including an implantable signal/pulse generator (IPG) and one or more electrodes (152, 152). The IPG is implanted in the mastoid area (143) of the skull (140) and communicates with at least one external appliance (230), such as a Behind-the-Ear (BTE) unit (100). In a preferred embodiment, the system is capable of open- and closed-loop operation. In closed-loop operation, at least one SCU includes a sensor, and the sensed condition is used to adjust stimulation parameters.

Abstract: Methods of providing therapy to a patient are provided. In one method, the patient has a neuron to which a sub-threshold biological electrical stimulus is applied. The method comprises applying electrical noise energy to the neuron, wherein resonance between the biological electrical stimulus and the electrical noise energy is created, such that an action potential is propagated along the axon of the neuron. In another method, the patient has a neuron to which a supra-threshold biological electrical stimulus is applied. This method comprises applying supra-threshold electrical noise energy to the neuron, thereby preventing an action potential from being propagated along the axon of the neuron. Still another method comprises applying an electrical stimulus to a neuron, and applying supra-threshold electrical noise energy to the neuron, thereby preventing or reversing any neurological accommodation of the neuron that may occur in response to the electrical stimulus.

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: An implantable microstimulator includes an elongate casing, a flap coupled directly to the casing, and electrodes attached to the flap such that the electrodes extend laterally relative to the longitudinal axis of the casing. The electrodes are coupled to active circuitry that is housed within the casing. Due to the lateral arrangement of the electrodes relative to the casing, effective operation of the microstimulator may still occur even after the microstimulator migrates away from the target stimulation site. Since there are not any leads associated with the microstimulator, the entire microstimulator, including the electrodes and the casing, is implanted adjacent to the target stimulation site. The electrodes may be configured for mono-polar or multi-polar stimulation. In one example, the microstimulator includes an insulative coating on the casing and the coating and the flap are contiguous.

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: A stimulation system is described that includes an implantable microstimulator. A tail may be coupled to a distal end of the implantable microstimulator. In one embodiment, the stimulation system includes an implantation tool that includes an insertion cannula, a handle, a bushing, and a detachable blunt dissector tip. The bushing is situated within the insertion cannula and may position the implantable microstimulator longitudinally within the insertion cannula when the implantable microstimulator is placed within the insertion cannula. The detachable blunt dissector tip may be attached to the tail of the implantable microstimulator. The stimulation system may further comprise an end cap that includes an upper portion and a base portion conformable over at least a portion of curved tissue. An open trough extends through the base upper portions and may be configured to guide the implantation tool through the tissue at various angles.

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: A system and method are provided for both recharging and communicating with a stimulator having a rechargeable battery, which stimulator is implanted deeply in the body, in particular where the stimulator is a microstimulator, the system includes a base station and an external device, for instance a chair pad. The chair pad may contain an antenna/charging coil and a booster coil. The antenna/charging coil can be used for charging the rechargeable battery and also for communicating with the stimulator using frequency shift keying and on-off keying. The booster coil can be used to recharge a battery depleted to zero volts. The base station connected to the chair pad may be used to power the antenna/charging coil and the booster coil.

Abstract: Systems of techniques for controlling charge flow during the electrical stimulation of tissue. In one aspect, a method includes receiving a charge setting describing an amount of charge that is to flow during a stimulation pulse that electrically stimulates a tissue, and generating and delivering the stimulation pulse in a manner such that an amount of charge delivered to the tissue during the stimulation pulse accords with the charge setting.

Abstract: Architectures for implantable stimulators having N electrodes are disclosed. The architectures contains X current sources, or DACs. In a single anode/multiple cathode design, one of the electrodes is designated as the anode, and up to X of the electrodes can be designated as cathodes and independently controlled by one of the X DACs, allowing complex patient therapy and current steering between electrodes. The design uses at least X decoupling capacitors: X capacitors in the X cathode paths, or one in the anode path and X?1 in the X cathode paths. In a multiple anode/multiple cathode design having X DACs, a total of X?1 decoupling capacitors are needed. Because the number of DACs X can typically be much less than the total number of electrodes (N), these architectures minimize the number of decoupling capacitors which saves space, and ensures no DC current injection even during current steering.

Abstract: A method for configuring stimulation pulses in an implantable stimulator device having a plurality of electrodes is disclosed, which method is particularly useful in adjusting the electrodes by current steering during initialization of the device. In one aspect, a set of ideal pulses for patient therapy is determined, in which at least two of the ideal pulses are of the same polarity and are intended to be simultaneous applied to corresponding electrodes on the implantable stimulator device during an initial duration. These pulses are reconstructed into fractionalized pulses, each comprised of pulse portions. The fractionalized pulses are applied to the corresponding electrodes on the device during a final duration, but the pulse portions of the fractionalized pulses are not simultaneously applied during the final duration.

Abstract: Systems of techniques for controlling charge flow during the electrical stimulation of tissue. In one aspect, a method includes receiving a charge setting describing an amount of charge that is to flow during a stimulation pulse that electrically stimulates a tissue, and generating and delivering the stimulation pulse in a manner such that an amount of charge delivered to the tissue during the stimulation pulse accords with the charge setting.

Abstract: Systems and techniques for controlling the stimulation of tissue. In one aspect, an apparatus includes an implantable stimulation device to elicit a response in a tissue by delivering one or more stimuli. The stimulation device includes a stimulus delivery element to deliver the one or more stimuli to elicit the response, a memory to store a range value identifying a range of values of a stimulation parameter relative to a first value, and a controller to control delivery of the stimuli by the stimulus delivery element in accordance with the range value. The stimulation parameter characterizes the stimuli to be delivered by the stimulation device.

Abstract: Methods of using unidirectionally propagating action potentials (UPAPs) for vagus nerve stimulation and for certain disorders are provided. Stimulators capable of creating such UPAPs include, but are not limited to, miniature implantable stimulators (i.e., microstimulators), possibly with programmably configurable electrodes.

Abstract: A system and method for applying electrical stimulation or drug infusion to nervous tissue of a patient to treat epilepsy, movement disorders, and other indications uses at least one implantable system control unit (SCU) (110), including an implantable signal/pulse generator (IPG) and one or more electrodes (152, 152?). The IPG is implanted in the mastoid area (143) of the skull (140) and communicates with at least one external appliance (230), such as a Behind-the-Ear (BTE) unit (100). In a preferred embodiment, the system is capable of open- and closed-loop operation. In closed-loop operation, at least one SCU includes a sensor, and the sensed condition is used to adjust stimulation parameters.

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: A method and system of providing therapy to a patient implanted with an array of electrodes is provided. Electrical stimulation current is conveyed from at least two of the electrodes to at least one of the electrodes along at least two electrical paths through tissue of the patient, and the electrical stimulation current is shifted between the electrical paths by actively adjusting one or more finite resistances respectively associated with one or more of the electrical paths.

Abstract: Methods of treating a medical condition include applying at least one stimulus to a motor cortex within a brain of a patient with an implanted system control unit in accordance with one or more stimulation parameters. Systems for treating a medical condition include a system control unit implanted within the patient that is configured to apply at least one stimulus to a motor cortex within a brain of a patient in accordance with one or more stimulation parameters.

Abstract: An exemplary implantable stimulator includes at least one electrode contact array and at least one additional electrode contact. Both the electrode contact array and the additional electrode contact are disposed on an external surface of the stimulator. The electrode contact array includes multiple electrode contacts that are configured to have a first polarity. The additional electrode is configured to have a second polarity. One or more of the electrode contacts disposed on the stimulator are configured to deliver monopolar stimulation and/or multipolar stimulation. Exemplary methods of stimulating a stimulation site within a patient include providing at least one electrode contact array and at least one additional electrode contact. Both the electrode contact array and the additional electrode contact are disposed on an external surface of the stimulator. The electrode contact array includes multiple electrode contacts that are configured to have a first polarity.

Abstract: Systems and methods are provided for applying electrical stimulation and/or introducing one or more stimulating drugs to the brain to treat or prevent aphasia, including through use of at least one system control unit (SCU) for controlling electrical pulses delivered via electrodes implanted in the brain and/or for producing drug infusion pulses to targeted areas in the brain.