Abstract: Systems and methods for enhancing or affecting neural stimulation efficiency and/or efficacy are disclosed. In one embodiment, a system and/or method may apply electromagnetic stimulation to a patient's nervous system over a first time domain according to a first set of stimulation parameters, and over a second time domain according to a second set of stimulation parameters. The first and second time domains may be sequential, simultaneous, or nested. Stimulation parameters may vary in accordance with one or more types of duty cycle, amplitude, pulse repetition frequency, pulse width, spatiotemporal, and/or polarity variations. Stimulation may be applied at subthreshold, threshold, and/or suprathreshold levels in one or more periodic, aperiodic (e.g., chaotic), and/or pseudo-random manners. In some embodiments stimulation may comprise a burst pattern having an interburst frequency corresponding to an intrinsic brainwave frequency, and regular and/or varying intraburst stimulation parameters.

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: Methods and systems for treating movement disorders are disclosed. A method in accordance with one embodiment can include determining that the movement disorder affects the patient's gait, oral functioning, and/or other functioning, and applying electrical stimulation proximate to the interhemispheric fissure, the Sylvian fissure, or between the two fissures, respectively. In another embodiment, the method can include selecting at least one neural process from among a plurality of processes sequentially carried out by a patient to cause a muscle movement in the patient (e.g., a planning process, an initiation process, and an execution process), and applying electrical stimulation to a location of the patient's brain associated with the at least one neural process.

Abstract: Methods and systems for treating movement disorders are disclosed. A method in accordance with one embodiment can include determining that the movement disorder affects the patient's gait, oral functioning, and/or other functioning, and applying electrical stimulation proximate to the interhemispheric fissure, the Sylvian fissure, or between the two fissures, respectively. In another embodiment, the method can include selecting at least one neural process from among a plurality of processes sequentially carried out by a patient to cause a muscle movement in the patient (e.g., a planning process, an initiation process, and an execution process), and applying electrical stimulation to a location of the patient's brain associated with the at least one neural process.

Abstract: Methods and systems for treating movement disorders are disclosed. A method in accordance with one embodiment can include determining that the movement disorder affects the patient's gait, oral functioning, and/or other functioning, and applying electrical stimulation proximate to the interhemispheric fissure, the Sylvian fissure, or between the two fissures, respectively. In another embodiment, the method can include selecting at least one neural process from among a plurality of processes sequentially carried out by a patient to cause a muscle movement in the patient (e.g., a planning process, an initiation process, and an execution process), and applying electrical stimulation to a location of the patient's brain associated with the at least one neural process.

Abstract: The following disclosure describes several methods and apparatus for intracranial electrical stimulation to treat or otherwise effectuate a change in neural-functions of a patient. Certain embodiments of methods in accordance with the invention electrically stimulate the brain at a stimulation site where neuroplasticity is occurring or is expected to occur. The stimulation site may be different than the region in the brain where neural activity is typically present to perform the particular neural function according to the functional organization of the brain. In one embodiment in which neuroplasticity related to the neural-function occurs in the brain, the method can include identifying the location where such neuroplasticity is present or expected to occur. In an alternative embodiment in which neuroplasticity is not occurring in the brain, an alternative aspect is to induce neuroplasticity at a stimulation site where it is expected to occur.

Abstract: A method for playing a game by first and second players includes assigning first type characters and second type characters to the first and second players. At a first turn, random numbers relating to each of the first type characters are used to concurrently or simultaneously position the first type characters on a game board. Similarly, at a second turn, random numbers relating to each of the second type characters are used to concurrently or simultaneously position the second type characters on the game board. A game play event, such as a battle or contest, may be initiated between the first and second players based on the relative positioning of the first and second players at the game board. In other examples, the first characters may have attributes or resources that can be developed and used in game play events, or in achieving an end goal of the game.

Abstract: Systems and methods for neural stimulation may include a stimulus unit; a first electrode assembly having a first set of contacts; and a second set of contacts. The stimulus unit can be an implantable pulse generator including a first terminal that can be biased at a first signal polarity and a second terminal that can be biased at a second signal polarity. The first electrode assembly includes a support member configured to be placed at the stimulation site, the first set of contacts carried by the support member, and a first lead configured to be attached to the first terminal of the implantable pulse generator for biasing the surface contacts at the first polarity. The second set of contacts is detached from the surface electrode assembly. The second set of contacts can be one or more conductive elements fixed to or forming portions of the implantable pulse generator, or a separate electrode array.

Abstract: Systems and methods for varying electromagnetic and adjunctive neural therapies are disclosed. A method in accordance with one embodiment includes applying electromagnetic signals to a target neural population of a patient over a first period of time in accordance with a first mode (e.g., including signal delivery to the central nervous system or peripheral nervous system, via implanted or non-implanted devices). The method can further include applying electromagnetic stimulation to the patient over a second period of time in accordance with a second mode different than the first mode. Varying the mode between the first period of time and second period of time can increase the efficacy and/or longevity of the stimulation. Systems in accordance with other embodiments can support multiple signal delivery devices.

Abstract: Systems and methods for enhancing or affecting neural stimulation efficiency and/or efficacy are disclosed. In one embodiment, a system and/or method may apply electromagnetic stimulation to a patient's nervous system over a first time domain according to a first set of stimulation parameters, and over a second time domain according to a second set of stimulation parameters. The first and second time domains may be sequential, simultaneous, or nested. Stimulation parameters may vary in accordance with one or more types of duty cycle, amplitude, pulse repetition frequency, pulse width, spatiotemporal, and/or polarity variations. Stimulation may be applied at subthreshold, threshold, and/or suprathreshold levels in one or more periodic, aperiodic (e.g., chaotic), and/or pseudo-random manners. In some embodiments stimulation may comprise a burst pattern having an interburst frequency corresponding to an intrinsic brainwave frequency, and regular and/or varying intraburst stimulation parameters.

Abstract: Methods and systems for intracranial neurostimulation and/or sensing are disclosed. An intracranial signal transmission system in accordance with an embodiment of the invention includes a generally electrically insulating body having a head portion configured to be positioned at least proximate to an outer surface of a patient's skull, and a shaft portion configured to extend into an aperture in the patient's skull. The system can further include at least one electrical contact portion integrated with the support body. The at least one electrical contact portion can be positioned to transfer electrical signals to, from, or both to and from the patient's brain via an aperture in the patient's skull.

Abstract: Methods and systems for treating movement disorders are disclosed. A method in accordance with one embodiment can include determining that the movement disorder affects the patient's gait, oral functioning, and/or other functioning, and applying electrical stimulation proximate to the interhemispheric fissure, the Sylvian fissure, or between the two fissures, respectively. In another embodiment, the method can include selecting at least one neural process from among a plurality of processes sequentially carried out by a patient to cause a muscle movement in the patient (e.g., a planning process, an initiation process, and an execution process), and applying electrical stimulation to a location of the patient's brain associated with the at least one neural process.

Abstract: Systems and methods for neural stimulation may include a stimulus unit; a first electrode assembly having a first set of contacts; and a second set of contacts. The stimulus unit can be an implantable pulse generator including a first terminal that can be biased at a first signal polarity and a second terminal that can be biased at a second signal polarity. The first electrode assembly includes a support member configured to be placed at the stimulation site, the first set of contacts carried by the support member, and a first lead configured to be attached to the first terminal of the implantable pulse generator for biasing the surface contacts at the first polarity. The second set of contacts is detached from the surface electrode assembly. The second set of contacts can be one or more conductive elements fixed to or forming portions of the implantable pulse generator, or a separate electrode array.

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: Microdevice-based electrode assemblies and associated neurostimulation systems, devices and methods are disclosed. A system in accordance with a particular embodiment includes a microdevice positioned to send signals or fluids to the patient, and/or to receive signals or fluids from the patient. The microdevice can include a housing having an external surface, and a signal/fluid transmitter/receiver positioned within the housing and coupled to a terminal carried by the housing. The system can further include a patient-implantable, flexible support member attached to the external surface of the housing and carrying the housing. The system can still further include an interface carried by the support member and connected to the terminal, with the interface being positioned to direct signals or fluids into patient tissue, and/or receive signals or fluids from the patient tissue.

Abstract: Methods for providing electrical stimulation therapy to a cortex of a patient via a plurality of electrodes proximate to the cortex and a pulse generator implanted in the patient. One embodiment of a method in accordance with the invention comprises determining whether the current applied via the plurality of electrodes results in a sufficient current density in the cortex. The current density, for example, may need to be high enough to induce a response in the patient for determining the activation threshold of the specific stimulation site, or the current density may need to be high enough to perform a specific therapy. If the current density is not sufficient, the method continues by selecting a subset of the plurality of electrodes, and applying electrical current to the cortex via the subset of the electrodes.

Abstract: Electrode configurations for reducing invasiveness and/or enhancing neural stimulation efficacy, and associated methods, are disclosed. A method in accordance with one embodiment of the invention for treating a brain disorder includes identifying a target neural structure within a patient's skull and implanting an electrode device within the patient's skull so that an axis that is generally normal to the skull proximate to the electrode device and that passes through at least one electrical contact of the electrode device is offset from the target neural structure. The method further includes stimulating the target neural structure by applying an electrical signal to the at least one electrical contact. In particular embodiments, the electrode device can be positioned between, along, across, or adjacent to a fissure, recess, groove, and/or vascular structure of the patient's brain.

Abstract: Systems and methods for enhancing or affecting neural stimulation efficiency and/or efficacy are disclosed. In one embodiment, a system and/or method may apply electromagnetic stimulation to a patient's nervous system over a first time domain according to a first set of stimulation parameters, and over a second time domain according to a second set of stimulation parameters. The first and second time domains may be sequential, simultaneous, or nested. Stimulation parameters may vary in accordance with one or more types of duty cycle, amplitude, pulse repetition frequency, pulse width, spatiotemporal, and/or polarity variations. Stimulation may be applied at subthreshold, threshold, and/or suprathreshold levels in one or more periodic, aperiodic (e.g., chaotic), and/or pseudo-random manners. In some embodiments stimulation may comprise a burst pattern having an interburst frequency corresponding to an intrinsic brainwave frequency, and regular and/or varying intraburst stimulation parameters.

Abstract: Methods and systems for treating movement disorders are disclosed. A method in accordance with one embodiment can include determining that the movement disorder affects the patient's gait, oral functioning, and/or other functioning, and applying electrical stimulation proximate to the interhemispheric fissure, the Sylvian fissure, or between the two fissures, respectively. In another embodiment, the method can include selecting at least one neural process from among a plurality of processes sequentially carried out by a patient to cause a muscle movement in the patient (e.g., a planning process, an initiation process, and an execution process), and applying electrical stimulation to a location of the patient's brain associated with the at least one neural process.

Abstract: Methods for treating neurological disorders, including neuropsychiatric and neuropsychological disorders, and associated systems are disclosed. One such method includes identifying one or more neural populations, including a cortical target neural population, associated with a neurological condition. The method can further include comparing a patient-specific measure of a characteristic parameter for a selected one of the neural populations with a target measure for the same parameter. If the patient-specific measure differs from the target measure by at least a target amount, the method can include selecting an electrical signal polarity, frequency, or both polarity and frequency based at least in part on the difference between the patient-specific measure and the target measure.