The present disclosure is directed generally toward systems and methods for applying, adjusting, or varying electromagnetic and adjunctive neural therapies.
A wide variety of mental and physical processes are controlled or influenced by neural activity in particular regions of the brain. For example, the neural functions in some areas of the brain (i.e., the sensory or motor cortices) are organized according to physical or cognitive functions. Several areas of the brain appear to have distinct functions in most individuals. In the majority of people, for example, the areas of the occipital lobes relate to vision, the regions of the left inferior frontal lobes relate to language, and particular regions of the cerebral cortex appear to be consistently involved with conscious awareness, memory, and intellect.
Many problems or abnormalities can be caused by damage, disease and/or disorders in the brain. Effectively treating such abnormalities may be very difficult. For example, a stroke is a common condition that damages the brain. Strokes are generally caused by emboli (e.g., obstruction of a vessel), hemorrhages (e.g., rupture of a vessel), or thrombi (e.g., clotting) in the vascular system of a specific region of the brain. Such events generally result in a loss or impairment of a neural function (e.g., neural functions related to facial muscles, limbs, speech, etc.). Stroke patients are typically treated using various forms of physical therapy to rehabilitate the loss of function of a limb or another affected body part. Stroke patients may also be treated using physical therapy plus an adjunctive therapy, such as amphetamine treatment. For most patients, however, such treatments are minimally effective and little can be done to improve the function of an affected body part beyond the recovery that occurs naturally without intervention. As a result, many types of physical and/or cognitive deficits that remain after treating neurological damage or disorders are typically considered permanent conditions that patients must manage for the remainder of their lives.
Neurological problems or abnormalities are often related to electrical and/or chemical activity in the brain. Neural activity is governed by electrical impulses or “action potentials” generated in neurons and propagated along synaptically connected neurons. When a neuron is in a quiescent state, it is polarized negatively and exhibits a resting membrane potential typically between −70 and −60 mV. Through chemical connections known as synapses, any given neuron receives excitatory and inhibitory input signals or stimuli from other neurons. A neuron integrates the excitatory and inhibitory input signals it receives, and generates or fires a series of action potentials when the integration exceeds a threshold potential. A neural firing threshold, for example, may be approximately −55 mV.
It follows that neural activity in the brain can be influenced by electrical energy supplied from an external source such as a waveform generator. Various neural functions can be promoted or disrupted by applying an electrical current to the cortex or other region of the brain. As a result, researchers have attempted to treat physical damage, disease and disorders in the brain using electrical or magnetic stimulation signals to control or affect brain functions.
Transcranial electrical stimulation (TES) is one such approach that involves placing an electrode on the exterior of the scalp and delivering an electrical current to the brain through the scalp and skull. Another treatment approach, transcranial magnetic stimulation (TMS), involves producing a magnetic field adjacent to the exterior of the scalp over an area of the cortex. Yet another treatment approach involves direct electrical stimulation of neural tissue using implanted electrodes.
The neural stimulation signals used by these approaches may comprise a series of electrical or magnetic pulses that can affect neurons within a target neural population. Stimulation signals may be defined or described in accordance with stimulation signal parameters, including pulse amplitude, pulse frequency, duty cycle, stimulation signal duration, and/or other parameters. Electrical or magnetic stimulation signals applied to a population of neurons can depolarize neurons within the population toward their threshold potentials. Depending upon stimulation signal parameters, this depolarization can cause neurons to generate or fire action potentials. Neural stimulation that elicits or induces action potentials in a functionally significant proportion of the neural population to which the stimulation is applied is referred to as supra-threshold stimulation; neural stimulation that fails to elicit action potentials in a functionally significant proportion of the neural population is defined as sub-threshold stimulation. In general, supra-threshold stimulation of a neural population triggers or activates one or more functions associated with the neural population, but sub-threshold stimulation by itself does not trigger or activate such functions. Supra-threshold neural stimulation can induce various types of measurable or monitorable responses in a patient. For example, supra-threshold stimulation applied to a patient's motor cortex can induce muscle fiber contractions in an associated part of the body.
More recently, direct cortical stimulation has been used to produce therapeutic, rehabilitative, and/or restorative neural activity, as disclosed in pending U.S. applications Ser. No. 09/802,808 Ser. No. 10/606,202, both assigned to the assignee of the present application, and both incorporated herein by reference. These techniques have been used to produce long lasting benefits to patients suffering from a variety of neural disorders. While these techniques have been efficacious, there is a continued need to improve the applicability of these methods to a wide variety of patients, and to further enhance the longevity of the effects produced by these methods.
The following disclosure describes several methods and systems for providing electromagnetic signals to treat or otherwise effectuate a change in a neural function of a patient. Several embodiments of methods and systems described herein are directed toward enhancing or otherwise inducing neuroplasticity to effectuate a particular neural function. Neuroplasticity refers to the ability of the brain to change or adapt over time. It was once thought that adult brains became relatively “hard wired” such that functionally significant neural networks could not change significantly over time or in response to injury. It has become increasingly more apparent that these neural networks can change and adapt over time so that meaningful function can be restored or developed in response to neurologic dysfunction such as brain injury. An aspect of several embodiments of methods and systems in accordance with the invention is to facilitate or provide the appropriate triggers for adaptive, restorative, and/or compensatory neuroplasticity. These appropriate triggers appear to cause or enable improved functional signaling capabilities within significant populations of neurons in a network.
Neural signals (e.g., stimulation signals) applied or delivered in various manners described herein may affect the excitability of a portion of a neural network involved in or associated with a functionally significant activity or task such that a selected population of neurons can become more strongly associated with that network. Because such a network will subserve a functionally meaningful activity or process (e.g., motor learning, cognition, processing emotional information/maintaining emotional state, or memory formation/consolidation), neurofunctional changes are more likely to be lasting because they are reinforced by natural use mechanisms. The nature of the stimulation in accordance with various embodiments of the invention may increase a likelihood that a stimulated population of neurons communicates with or links to other neurons in a functional network. In some embodiments, this may occur because action potentials are not actually caused or generally caused by the stimulation itself, but rather the action potentials are caused by interactions with other neurons in the network. Several aspects of the electromagnetic stimulation in accordance with selected embodiments of the invention increase the probability of restoring or developing neural functionality when the network is activated by a combination of electromagnetic stimulation and one or more favorable activities or processes. Such activities may comprise one or more types of behavioral therapy, for example, rehabilitation, limb use, cognitive behavioral therapy, an activity of daily living, or observation of other individuals performing relevant activities.
Various methods in accordance with embodiments of the invention can be used to treat particular symptoms in patients experiencing neurologic dysfunction arising from neurological damage, neurologic disease, neurodegenerative conditions, neuropsychiatric disorders, neuropsychological (e.g., cognitive or learning) disorders, and/or other conditions. Such neurologic dysfunction and/or conditions may correspond to Parkinson's Disease, essential tremor, Huntington's disease, stroke, traumatic brain injury, Cerebral Palsy, Multiple Sclerosis, a central and/or peripheral pain syndrome or condition, a memory disorder, dementia, Alzheimer's disease, an affective disorder, depression, bipolar disorder, anxiety, obsessive/compulsive disorder, Post Traumatic Stress Disorder (PTSD), an eating disorder, schizophrenia, Tourette's Syndrome, Attention Deficit Disorder, dyslexia, a phobia, an addiction (e.g., alcoholism or substance abuse), autism, epilepsy, a sleep disorder (e.g., sleep apnea), an auditory disorder (e.g., tinnitus or auditory hallucinations), a language disorder, a speech disorder (e.g., stuttering), migraine headaches, and/or one or more other disorders, states, or conditions. In other embodiments identical or at least generally similar methods and systems can be used to enhance the neural functioning of patients who otherwise function at normal or even above normal levels.
In general, a stimulation site may be defined as an anatomical region, location, or site at which electromagnetic signals (e.g., stimulation signals) may be applied or delivered to the patient. Such signals may be intended to directly and/or indirectly affect one or more target neural populations, for example, by passing or traveling to, into, through, and/or near a target neural population. In various embodiments, one or more stimulation sites and/or target neural populations may reside upon or within one or more cortical regions, for example, a portion of the premotor cortex, the motor cortex, the supplementary motor cortex, the somatosensory cortex, the prefrontal cortex, and/or another cortical region. Additionally or alternatively, one or more stimulation sites and/or target neural populations may reside elsewhere, for example, in a subcortical or deep brain region, within or upon the cerebellum, and/or upon or proximate to portions of the spinal cord and/or one or more cranial or other peripheral nerves.
A target neural population and/or a stimulation site may be identified and/or located in a variety of manners, for example, through one or more procedures involving the identification of anatomical features or landmarks; electrophysiological signal measurement (e.g., electroencephalography (EEG), electromyography (EMG), silent period, coherence, and/or other measurements); neural imaging (e.g., Magnetic Resonance Imaging (MRI), functional MRI (fMRI), Diffusion Tensor Imaging (DTI), Perfusion Weighted Imaging (PWI), Positron Emission Tomography (PET), single photon emission computed tomography (SPECT), optical imaging (e.g., near infrared-spectroscopy (NIRS) or optical tomography (OT)), Magnetoencephalography (MEG), and/or another technique); neurofunctional mapping (e.g., using TMS and/or intraoperative stimulation); vascular imaging (e.g., Magnetic Resonance Angiography (MRA)); chemical species analysis (e.g., Magnetic Resonance Spectroscopy (MRS)); and/or another type of functional and/or structural anatomic assessment technique (e.g., Transcranial Doppler ultrasonography (TCD)).
Certain methods in accordance with embodiments of the invention electrically and/or magnetically stimulate the brain at a stimulation site where neuroplasticity is occurring or has occurred, and/or where neuroplasticity is expected to occur. In particular embodiments, the manner in which the electromagnetic signals are applied to the brain and/or other neural tissue can be varied over the course of two or more time periods. For example, a type of signal source and/or a waveform, amplitude, pulse pattern, and/or location at which stimulation is applied can be varied from one time period to the next. In still further embodiments, the manner in which one or more adjunctive therapies are applied during a therapy program can be varied from one time period to another. For example, a type of behavioral therapy and/or a manner in which a patient undergoes such therapy can be varied. The adjunctive therapy can occur simultaneously with the electromagnetic stimulation, or at other times, depending upon the patient's condition.
Other aspects of the invention are directed to systems that support different modes via which electromagnetic signals are applied to the patient. For example, a system in accordance with one aspect of the invention includes a controller that is coupleable to at least two different kinds of signal delivery devices. The controller can provide electromagnetic stimulation in accordance with different modes, depending upon which device it is coupled to. The signal delivery devices can be selected to include (for example) implanted cortical electrodes, subcortical or deep brain electrodes, cerebellar electrodes, spinal column electrodes, vagal nerve (or other cranial or peripheral nerve) electrodes, transcranial electrodes and/or transcranial magnetic stimulators.
The specific details of certain embodiments of the invention are set forth in the following description and in
A. Overall Systems And Methods
The method 100 may include a diagnostic procedure 102 involving identifying at least one stimulation site corresponding to an anatomical location at which stimulation signals may be applied or delivered to one or more target neural populations. In various embodiments, such neural populations may reside within the central nervous system, and in particular embodiments, one or more target neural populations may reside within the brain. In some embodiments, particular target neural populations may include one or more portions of the peripheral nervous system.
In one approach, a set of stimulation sites may be particular locations of the brain and/or the spinal cord where an intended neural activity related to a given type of neural function is present or is expected to be present. For example, the stimulation site may be particular neural regions and/or cortical structures that are expected to direct, effectuate, and/or facilitate specific neural functions in most individuals. In another approach, the stimulation site may be a location of the brain that supports or is expected to support the intended neural function.
The diagnostic procedure 102 may include identifying one or more anatomical landmarks on the patient that correspond to such neural populations, regions, and/or structures. The anatomical landmarks serve as reference points for identifying or approximately identifying a neural location (e.g., a brain or spinal cord location) where an intended neural activity may occur. Thus, one aspect of the diagnostic procedure 102 may include referencing a stimulation site relative to anatomical landmarks. More specifically, identifying an anatomical landmark may include visually determining the location of one or more reference structures (e.g., visible cranial landmarks), and locating underlying brain regions or structures (e.g., the motor strip and/or the Sylvian fissure) relative to the external location of the reference structures. Such reference structures may include, for example, the bregma, the midsagittal suture, and/or other well-known cranial or other landmarks referenced in a manner understood by those skilled in the art. The methods for locating an underlying brain structure typically involve measuring distances and angles relative to the cranial topography, as is known in the art of neurosurgery.
The diagnostic procedure 102 may additionally or alternatively include identifying one or more enhanced-precision or patient-specific stimulation sites and/or target neural populations. A patient-specific stimulation site may be identified in various manners, including one or more of MRI, fMRI, DTI, MRS, MRA, PET, SPECT, MEG, NIRS, OT, EEG, intraoperative mapping, and/or another technique capable of localizing, measuring, or monitoring neuroanatomical structures, neurofunctional or neurometabolic activity or activity correlates, and/or chemical species concentrations.
In one embodiment, the diagnostic procedure 102 includes identifying, generating, or characterizing an intended neural activity in the brain at a supplementary, auxiliary, derivative, secondary, or peripheral location that is different, distinct, or remote from a normal location, and determining where the intended neural activity is actually present in the brain. In an alternative embodiment, the diagnostic procedure 102 can be performed by identifying a stimulation site where neural activity has changed in response to a change in the neural function.
The method 100 continues with a positioning procedure 104 involving positioning at least one electromagnetic signal delivery device or signal transfer element relative to an identified stimulation site, and a stimulating procedure 106 involving applying an electromagnetic signal to the signal delivery device. Several embodiments of the positioning procedure 104 include positioning two or more electrodes at a stimulation site (e.g., in a bipolar arrangement), but other embodiments of the implanting procedure involve positioning only one electrode at a stimulation site and another electrode remotely from the stimulation site (e.g., in a unipolar arrangement). In still further embodiments, stimulation can be applied without implanting electrodes (e.g., by delivering stimulation transcranially). Particular embodiments include changing the signal delivery mode (e.g., the type of signal delivery device and/or the location to which signals are directed) during the course of a treatment regimen (process portion 108).
The brain 230 of
The neural activity in the first region 232a, however, can be impaired. In one embodiment, the diagnostic procedure 102 begins by taking an image of the brain 230 that is capable of detecting neural activity to determine whether the intended neural activity associated with the particular neural function of interest is occurring at the region of the brain 230 where it normally occurs according to the functional organization of the brain, and/or in a manner in which it would normally be expected to occur.
The two hemispheres 231a and 231b of the brain 230 are connected via the corpus callosum, which facilitates information transfer between the hemispheres. Although each hemisphere 231a, 231b generally exerts majority control over motor and/or sensory functions on the opposite or contralateral side of the patient's body, each hemisphere typically also exerts some level of control and/or influence over motor and/or sensory functions on the same or ipsilateral side of the patient's body. Moreover, through transcallosal connections, neural activity in one hemisphere may influence or modulate neural activity, e.g., neuroplasticity, in the opposite hemisphere. The location in the brain 230 that exerts influence on an ipsilateral body function frequently is proximate to or subsumed within the location of the brain associated with a corollary body function. Hence, as suggested in
The stimulation sites can be characterized as ipsilateral or contralateral, with reference to particular brain regions or body functions, as described above. In some instances, it may be useful to describe the stimulation sites with reference to an affected neural population. In such instances “ipsilesional” is used to refer to a site that is at the same hemisphere as an affected neural population, and “contralesional” is used to refer to a site that is at the opposite hemisphere as the affected neural population, whether the affected neural population is affected by a lesion or another condition. Either set of terms may be used herein to characterize the site, depending upon the particular context.
The diagnostic procedure 102 may utilize evidence of a set of neural structures, a level of neural activity, neuroplasticity, and/or chemical species information within the brain to identify the location of a stimulation site that is expected to be more responsive to the results of an electrical, magnetic, sonic, genetic, biologic, pharmaceutical, mechanical, thermal, or other procedure to facilitate or effectuate a desired neural function. One embodiment of the diagnostic procedure 102 involves measuring, estimating, or characterizing types or levels of neural activity or chemical species in particular brain regions relative to other (e.g., corollary) brain regions, a set of reference brain regions (e.g., corresponding to a population of healthy individuals), and/or different time periods.
Another embodiment of the diagnostic procedure 102 involves generating an intended neural activity remotely from the first region 232a of the brain, and then detecting or sensing the location(s) in the brain where the intended neural activity has been generated. The intended neural activity can be generated by causing a signal to be generated within and/or sent to the brain. For example, in the case of a patient having an impaired limb, the affected limb is moved and/or stimulated while the brain is scanned using a known imaging technique that can detect neural activity (e.g., fMRI, PET, etc.). In one specific embodiment, the affected limb can be moved by a practitioner or the patient, stimulated by sensory tests (e.g., pricking), or subjected to peripheral electrical stimulation. In another embodiment, the patient can attempt to move the affected limb, or imagine or visualize moving the affected limb in one or more manners. The attempted or imagined movement/actual movement/stimulation of the affected limb produces a neural signal corresponding to the limb (e.g., a peripheral neural signal) that is expected to generate a response neural activity in the brain. The location(s) in the brain where this response neural activity is present can be identified using the imaging technique.
Depending upon embodiment details, subthreshold and/or suprathreshold stimulation signals may be applied to particular stimulation sites.
Several embodiments of methods for affecting or enhancing neural activity in accordance with the invention are expected to provide lasting results that promote a desired neural function. At least some of these embodiments may also provide lasting results because electromagnetic stimulation therapies described herein may be applied or delivered to a patient in association with or simultaneously with one or more synergistic or adjunctive therapies. Such synergistic or adjunctive therapies may include or involve the patient's performance or attempted performance of one or more behavioral therapies, activities, and/or tasks. Aspects of the electromagnetic therapy and/or the adjunctive therapy can be varied during the course of treatment to extend and/or otherwise enhance the effects of these treatments, as described below.
B. Methods For Altering Treatment During A Treatment Program
Signals applied in accordance with any of the foregoing modes can optionally be associated with one or more adjunctive therapies in addition to the electromagnetic therapy. As used herein, an adjunctive therapy refers to a therapy that is different than the electromagnetic signals, but is provided in association or conjunction with the electromagnetic signals. For example, an adjunctive therapy can include a behavioral therapy or a drug therapy. The adjunctive therapy may in some cases be provided simultaneously with the electromagnetic signals, and in other cases, may be provided before or after the electromagnetic signals. Further details of specific types of adjunctive therapies are described later with respect to
In process portion 606, a determination is made as to whether continued treatment in accordance with the current mode (e.g., the first mode or first mode set) is potentially beneficial. If so, the process returns to process portion 604 for additional treatment in accordance with that mode. If not, then in process portion 608, an evaluation is made as to whether treatment during a subsequent (e.g., a second) period of time with a different mode (e.g., a second mode that is different from a first mode, or a second mode set that involves additional or fewer modes than a first mode set), would be potentially beneficial. If it is determined that such a treatment would not be potentially beneficial, the treatment program is discontinued (process portion 620).
If instead it is determined at process portion 608 that treatment during a subsequent period of time with a different mode may be beneficial to the patient, the process 600 can further include determining whether or not to conduct an analysis to determine the modifications to be made for treatment during the subsequent period of time (process portion 610). For example, in some cases, it may be clear, based on past experience and the patient's recovery performance, in what manner the treatment program should be varied during the subsequent time period. In these cases, the process can move directly to process portion 611, which includes directing an application of electromagnetic signals during the subsequent period of time in accordance with a different mode. If it is not immediately clear which mode (or modes) should be adopted during the subsequent time period, the process 600 can move to process portion 612, which includes measuring the extent of the patient's recovery and/or functional gains. This measurement can be made by having the patient perform tests or undergo other diagnostic procedures, in most cases, similar or identical to diagnostic procedures the patient performed before initiating the program in process portion 602. In process portion 614, the results are analyzed. For example, by comparing the results after the patient has completed treatment for the first period of time with results obtained either before treatment or during treatment during the first period of time, a practitioner can identify the progress the patient has made. The practitioner can then review the available alternate modes and select one or more modes expected to provide an enhanced effect when applied during the subsequent period of time.
After completing the analysis in process portion 614, the practitioner can again assess whether treatment for the subsequent period of time is still appropriate (process portion 616). If not, (for example, if the analysis completed in process portion 614 indicates that such treatment would not be beneficial), the program is discontinued (process portion 620). If subsequent treatment is appropriate, the practitioner can determine whether the treatment program should be continued with a new mode or the current mode (process portion 618). For example, if the analysis completed in process portion 614 indicates that in fact continued treatment with the current mode remains appropriate, the process can return to process portion 604. If the analysis confirms that treatment with a new mode is appropriate, the practitioner can treat the patient during the subsequent period of time in accordance with the new mode (process portion 611). In process portion 611, the new mode may be selected from block 605 to be different than a previously used mode.
1. Signal Application Parameters
Signal application parameters refer generally to parameters, other than the mode, via which the practitioner can adjust the effect of the signals on the patient. For example, the practitioner can select the signal application parameters to have a facilitatory or an inhibitory effect on a target neural population. The signal parameters selected by the practitioner can include the current level, voltage level, polarity, waveform type, and/or duration or duty cycle of the signals applied to the patient. The current or voltage level can be selected to be a percentage of the patient's threshold response or level for a given target neural population. As described above, a threshold level can correspond to a signal level or magnitude necessary to trigger a motion response, a sensation, or another observable, measurable, or monitorable effect. When the signals are provided in a time-varying manner, the parameters can further include the width of pulses transmitted to the patient, an overall or representative frequency with which signals are transmitted to the patient, and/or a modulation function that identifies or specifies the manner in which the pulses are varied during treatment. Stimulation signals may be periodic or aperiodic (e.g., random, pseudo-random, or chaotic).
The electromagnetic signals described above can be provided over the course of hours, weeks and/or months in accordance with any of several schedules. For example, the electromagnetic signals can be applied during the first period for three hours per day, 3-5 days per week, for 2-8 or 3-6 weeks, via implanted cortical and/or other electrodes. The electromagnetic stimulation portion of the treatment may then be suspended for an intermediate period of time (e.g., several hours, days, weeks, or months) during which the patient may rest or consolidate neurofunctional gains, and/or still undergo adjunctive therapies. The patient may then undergo another stimulation therapy in accordance with another mode (e.g., via transcranial direct current stimulation (tDCS)) for a period of hours, days or weeks (e.g., one hour, twice a week for four weeks) during the second period of time.
Depending upon embodiment details or patient condition, stimulation therapy in accordance with a particular mode or set of modes may be provided over a limited duration time period (e.g., the first period), and stimulation therapy in accordance with a different mode or mode set may be provided over another limited duration time period or an ongoing or essentially permanent time period (e.g., the second period). Stimulation therapy provided in separate time periods may be directed toward identical, similar, or different types of neurologic dysfunction or patient symptoms. As an example, stimulation therapy during a limited duration first time period may be directed toward functional recovery following neurologic damage, and stimulation therapy during a long-term or ongoing second time period may be directed toward alleviating a central pain syndrome. As another example, stimulation during a limited duration first time period may be directed toward treating post-stroke depression (e.g., using TMS and/or tDCS) and/or restoring motor function (e.g., using a set of implanted cortical electrodes), while stimulation during a limited duration second time period may be directed toward restoring motor, language, and/or cognitive functions (e.g., using the same and/or a different set of implanted cortical electrodes).
In any of the foregoing embodiments, the electromagnetic signals may be preceded by or followed by conditioning stimuli. The conditioning stimuli can be provided immediately or nearly immediately before or after the primary therapeutic signals, and can be provided via a different mode. For example, if the primary therapeutic signals are provided by one or more implanted electrodes, the conditioning stimuli can be provided by tDCS or TMS. In particular embodiments, the conditioning stimuli can be provided within minutes or hours of the primary therapeutic signals, during either the first or second period of time. The conditioning stimuli may be provided in the same brain hemisphere as and/or the opposite brain hemisphere of the primary therapeutic stimulation. The conditioning stimuli are expected to enhance and/or preserve the effects of the primary therapeutic stimulation.
The selectable signal parameters can also include the location(s) at which signals are applied. For example, the signals may be applied to different sites of the patient's nervous system during different phases of a treatment regimen. The sites can be selected from at least the following locations: a location above the cerebral cortex, a location at the cerebral cortex, a location below the cerebral cortex, a cerebellar location, a spinal column location, a location proximate to a cranial (e.g., vagal) or other peripheral nerve, and a location proximate to a muscle. The location may also be varied within one of the above location parameters. For example, during one portion of a treatment regimen, the signals may be provided to one position above or at the cerebral cortex (e.g., proximate to the prefrontal cortex or motor cortex within a given brain hemisphere) and during another portion, the signals may be provided to another position, also above or at the cerebral cortex (e.g., proximate to the premotor cortex within the same or the opposite hemisphere).
In some situations, the selection of the target signal site (in addition to the mode via which the signals are delivered) may be influenced by evidence of changes the patient's brain may have undergone during a prior time period. For example, if it is determined that during the first period of time, the patient's brain has begun recruiting neurons at a site different than the site stimulated during the first period of time, then during the subsequent period of time, the location at which stimulation is provided can be adjusted to correlate more closely with the location at which the brain is recruiting neurons. In another example, it may become apparent after stimulating an ipsilesional stimulation site (e.g., a site in the same hemisphere as damaged or dysfunctional brain tissue) for the first period of time that stimulating a contralesional site may be beneficial. In particular, the ipsilesional stimulation may not have the desired effect or level of desired effect. In such a situation, stimulation during the subsequent period of time can be applied to a contralesional portion of the brain (e.g., the corresponding portion of the brain located in the opposite hemisphere), either alone or in combination with applying stimulation to the ipsilesional brain region.
A change in location may include combinations of any of the parameters described above. For example, during the first time period, the patient may be stimulated in the left hemisphere above the cortex, and during the second time period, the patient may be stimulated in the right hemisphere below the cortex. In some cases, the electrodes implanted in the patient's brain and/or other neuroanatomical location prior to the first period of time may be in a position to provide stimulation during the second period of time as well. In other embodiments, additional electrodes may be implanted prior to the second period of time.
In still further embodiments, the stimulation provided during the second period of time may not require implanting new electrodes, even if the electrodes implanted for stimulation during the first period of time are not positioned properly for stimulation during the second period of time. For example, stimulation provided during the second period of time may include transcranial direct current stimulation or tDCS, (discussed further below with reference to
2. Adjunctive Therapies
As described above, the adjunctive therapy can include one or more therapy types that are different than the electromagnetic signals applied as part of process portion 722. For example, the adjunctive therapy can include a systematized, directed behavioral activity, including a physical, cognitive, and/or psychiatric activity coordinated and possibly observed by a therapist. In terms of physical therapy, such activities can include grasping and releasing objects, stacking objects, placing objects in a box, manipulating objects, or other tasks that form part of a systematized physical therapy regimen. In at least some cases, these activities can form part of a standardized testing regimen as well, e.g., a Fugl-Meyer test.
The nature of the task can be selected depending upon the particular condition(s) the patient is suffering from. For example, if the patient is suffering from aphasia or another language-related disorder, the therapy task can be language-based and can include performing, attempting to perform, imagining patient performance of, and/or observing or noticing others perform any of a number of attempted speaking, listening, writing, and/or reading tasks. In some embodiments, the patient need not actually vocalize to successfully perform a task. Instead, the patient can be directed to merely think of a word, letter, phrase or other language component; or listen to or watch another individual perform the task. For example, the patient can be directed to silently generate a verb associated with a common noun, silently repeat a noun, silently retrieve a word based on a letter cue, or silently retrieve a word based on a visual cue. In particular cases, the patient can be directed to think of words beginning with the letter “c”, for example, or can be shown a picture of a cat and asked to think of the word represented by the picture. The patient can also be asked to respond non-verbally to an oral task that requires the patient to understand the difference between two auditory commands.
In other embodiments, the therapy activity can include a visual activity, auditory activity, gustatory activity, olfactory activity and/or haptic activity (e.g. pertaining to the sense of touch), again, depending upon the patient's specific disorder and/or symptoms. In some embodiments, an activity may comprise an observation activity. In general, an observation activity involves the patient observing or paying attention to one or more individuals who are performing particular activities or tasks or participating in or simulating particular behaviors (e.g., behaviors relating to movement, sensation, language, cognition, or emotion). In addition to actual performance or attempted performance of an activity or task, an observation activity may activate mirror neurons that are relevant to developing or restoring one or more types of functional abilities.
An observation activity may occur through real time or non-real time interaction (e.g., an audio/visual lesson or presentation) involving actual or simulated situations. Simulated situations may include patient observation of or interaction with another individual, a representation of another individual, or possibly a representation of the patient (e.g., using virtual reality). An observation activity may occur under the direction of or in response to instructions or suggestions received from a clinician or other individual; or in some instances an observation activity may be self-directed. Patient observation of others may further involve patient imagination of successful activity performance, or patient imitation of observed behaviors.
The adjunctive treatment need not be a systematized, directed physical therapy activity. For example, the adjunctive treatment can include activities of daily living (ADL). In other words, the patient can effectively perform adjunctive therapy by simply engaging in normal daily activities that might include getting dressed, eating, walking, talking and/or other activities. In still further embodiments, the adjunctive therapy need not include a behavioral therapy. For example, the adjunctive therapy can include a chemical substance or drug therapy. In any of these embodiments, the manner in which the adjunctive therapy is conducted, the type of adjunctive therapy undergone, and/or the presence or absence of any adjunctive therapy can be varied between the first time period and the second time period. In some embodiments, overall therapy provided during the first time period may be directed toward treating a first type of neurofunctional deficit or a first set of patient symptoms (e.g., hemiparesis), while the overall therapy provided during the second time period may be directed toward treating a second type of neurofunctional deficit or a second set of patient symptoms (e.g., aphasia). In other embodiments, the overall therapy provided to the patient during both time periods may be directed to a common deficit, but aspects of the overall therapy (e.g., the mode, signal delivery parameters, and/or adjunctive therapy) may differ from one time period to the next. The therapies provided during each time period may differ (e.g., due to different modes) while still being directed toward treatment of a common deficit.
For purposes of illustration, the variations in electromagnetic therapy parameters (e.g., mode) were described above independently of the variations in adjunctive therapy parameters. In practice, both parameters may be varied singly or in conjunction with each other in a wide variety of possible combinations. For example, the patient may undergo direct cortical stimulation via implanted electrodes, and may undergo directed physical therapy during a first time period. Both the electrical stimulation and the directed physical therapy may take place under the direct supervision of a trained practitioner. During the second time period, the patient may also receive direct cortical stimulation from the same or a different set of implanted electrodes, but may apply the stimulation by him or herself, or may have the stimulation triggered automatically without the direct involvement of a practitioner, or may have the stimulation provided in accordance with another mode. The adjunctive therapy during this second time period may shift from directed physical therapy to activities of daily living or other activities. For example, the patient may be coupled to a system that responds to feedback from the patient by automatically applying electromagnetic stimulation to the patient. If the adjunctive therapy is a physical activity (e.g., riding a stationary bike), the system can automatically detect the onset of the adjunctive therapy by detecting rotation of the bike wheels, and can automatically initiate or adjust electromagnetic stimulation by activating implanted electrodes via a wireless link. If the adjunctive therapy is a cognitive activity (e.g., responding to computer-based questions), the system can detect initiation of the adjunctive therapy by detecting an answer to a question, and can automatically initiate or adjust electromagnetic stimulation via the wireless link.
In another embodiments, the patient may receive practitioner-assisted electromagnetic therapy (e.g., via TMS or tDCS) during one period of time, and automated electromagnetic therapy in accordance with another mode (e.g., via an implanted electrode) during another period of time. In any of these embodiments, the manner in which the treatment is carried out (e.g., the mode, signal parameters and/or adjunctive therapy) is typically different when the treatment is directly supervised by a practitioner than it is when the treatment is not. This arrangement can allow the practitioner to directly supervise only those activities corresponding to particular treatment portions, while other (different) treatment portions can be carried out autonomously by a corresponding signal delivery system, or semiautonomously by the system with input from the patient.
3. Potential Results
One feature of many of the foregoing embodiments is that the manner(s) in which the electromagnetic therapy and/or the adjunctive therapy are conducted can be varied within and/or from one time period to another. One advantage of this feature is that it can reduce the likelihood for the patient's body to adapt or habituate to a particular type of electromagnetic and/or adjunctive therapy. As a result, the patient's neural system may be more likely to respond favorably to the therapy because the therapy varies. Another potential advantage associated with this feature is that it may improve the longevity of the effect achieved by the therapy. For example, it has been observed in some cases that a long-lasting effect of a combined electromagnetic/adjunctive therapy regimen completed during only a first period may tend to fall off somewhat over time. Accordingly, the second period of time may “boost” the effect achieved during the first period of time, and/or at least partially preserve the effects obtained during the first period of time. As a result, stimulation during the second period of time can enhance and/or increase the duration of the effects created during the first period of time. These effects can last for a period of at least days or weeks and in many cases, months or years, even though the treatment regimen (e.g., a series of treatment sessions over one, two or more periods of time) may take significantly less time.
Another feature of at least some of the foregoing embodiments is that they can produce a reduction in power consumed by one or more stimulation systems. This result can be achieved by combining modes, changing modes, and/or changing aspects of a particular mode. For example, switching from an implant mode to a nonimplant mode can effectively extend the life of an implanted power source. In another example, in certain situations switching from deep brain stimulation to cortical stimulation may result in a power savings, compared with using deep brain stimulation exclusively. If an implanted power source is non-rechargeable, combining modes, changing modes, and/or changing aspects of a mode may extend a power source lifetime (e.g., by 10%-50% or more) to a sufficient extent that the frequency of power source replacement surgeries may be decreased (e.g., by a commensurate or corresponding extent). Furthermore, combining or changing modes or altering mode aspects may eliminate the need for a power source replacement surgery following the use of a first implanted mode if the patient may be successfully treated using a second or subsequent non-implanted mode.
Still another feature of at least some of the foregoing embodiments is that the use of multiple modes (and/or multiple aspects of a particular mode) can synergistically enhance neural stimulation efficacy and/or address multiple symptoms and/or types of dysfunction. For example, deep brain stimulation may alleviate only some Parkinsonian symptoms, while cortical stimulation may relieve others (e.g., cognitive or affective symptoms). As another example, vagal nerve stimulation, TMS, and/or tDCS may treat an affective disorder such as depression or PTSD, while implanted cortical stimulation may (a) enhance such treatment, (b) facilitate the restoration or development of neural function associated with an affective or other disorder, or (c) treat another type of neurologic dysfunction from which the patient suffers (e.g., a pain syndrome). Similarly, peripheral stimulation can be used to address different symptoms than does CNS stimulation.
C. Systems for Applying Electromagnetic Stimulation
Referring now to
Referring to
In one aspect of this embodiment, the controller 962 can be operatively coupled to multiple signal delivery devices 950 in a sequential manner. Accordingly, the controller 962 can provide stimulation to one signal delivery device 950 at a time via a mode that is commensurate with the corresponding signal delivery device. In other embodiments, the controller 962 can be configured to transmit signals to the patient via multiple signal delivery devices 950 simultaneously. In any of these embodiments, the controller 962 can include a mode selector 967 via which a practitioner can select the mode of treatment applied to the patient. The practitioner can do so via a user interface 963 (e.g., a touch screen, knob, or other suitable device). The controller 962 can further include a limiter 966 that prevents inappropriate signals from being transmitted by the transmitter 968 when such signals are not consistent with the mode selected via the mode selector 967. For example, if a practitioner selects a mode that has associated with it a peak current or peak frequency value, the limiter 966 can prevent the transmitter 968 from transmitting signals that exceed those values. The mode selector 967 can be a hardware switch or a software switch, and the limiter 966 can also include a hardware or software switch.
In still a further aspect of this embodiment, the limiter 966 can prevent signals from being transmitted to a signal delivery device 950 when such signals are not appropriate for that signal delivery device. For example, the system 960 can include a facility (e.g., hardware and/or software) for identifying whether the signal delivery device 950 coupled to the transmitter 968 is a first signal delivery device 950a or a second signal delivery device 950b. If only certain types of signals (e.g., AC or DC) and/or a certain range of signal parameters (e.g., voltage, current, frequency) are appropriate for the first signal delivery device 950a, the limiter 966 can be configured to prevent inappropriate signals from being transmitted to the first signal delivery device 950a when the first signal delivery device 950a is coupled to the controller 962. In particular embodiments, each signal delivery device 950a, 950b . . . 950n can have an identifying code that is recognized by the controller 962 so that the controller can automatically permit only signals having the proper characteristics from being transmitted to a corresponding signal delivery device. For example, a signal typically applied to an implanted electrode may be a set of biphasic pulses, while a signal applied to a tDCS electrode may be a direct current signal. As another example, during a therapy period, the limiter 966 can automatically prevent the transmission of suprathreshold signals to one or more implanted electrodes, or limit the duration or number of suprathreshold signals applied to such electrodes. In particular embodiments, the system can include a hardware arrangement (e.g., differently shaped connection ports for different types of signal delivery devices, or radio frequency identification (RFID) devices, chips, or tags corresponding to different signal delivery devices) to identify the signal delivery devices. Appropriate software (e.g., similar to that used to identify printers and other peripheral devices attached to a personal computer) can be used in addition to or in lieu of the hardware arrangement.
Certain components of the signal supply 974 can be housed in an implanted unit and/or an external unit. For example, the controller 962 can include an implanted unit that autonomously controls the electrical signals without further action by a practitioner or other individual. Alternatively, the implanted unit can communicate with an external unit that provides instructions regarding the type of electromagnetic signals provided to the patient. A power supply 961 can also be housed in an internal and/or external unit, but need not necessarily be co-housed with the controller. Further aspects of systems that have the foregoing characteristics and include one or more types of signal delivery devices are described below with reference to
The implanted housing 954 can communicate via wireless telemetry with an external telemetry device 992. The external telemetry device 992 can form a portion of an external controller 964 that transfers program, control, data, and/or other signals (e.g., power signals) to and/or from the patient. Accordingly, the external controller 964 can include a hand-held unit 993 having a display screen 994, one or more input devices (e.g., keys, buttons, and/or a stylus 995), a processing unit, and one or more computer readable media for storing program instructions and data. The external controller 964 may provide a set of graphical menus or selection interfaces that provide a graphical user interface (GUI) to the practitioner. A practitioner can select modes using the hand-held unit 993 and can receive feedback (e.g., an indication of available modes and selected modes) via the display screen 994. In a particular embodiment shown in
The combination of cortical stimulation and deep brain stimulation may provide particular advantages to the patient in at least some embodiments. For example, deep brain stimulation can be used to “drive” or otherwise affect the excitability of a neural population within or proximate to the basal ganglia. The signals transmitted by the deep brain neural population can in turn affect neural populations at the cortex via neural projections, tracts and/or other neural signaling pathways. The response by the cortical neural population can be enhanced or modulated by the addition of the cortical stimulation, and the cortical neural population's response may in turn affect a deep brain population. In particular embodiments, the electromagnetic signals provided to a cortical neural population by the system 960 can have a selected temporal relationship to the electromagnetic signals provided to the deep brain population by the system 960. For example, the system 960 can stimulate the deep brain population and then follow up with stimulation to the cortical population at or close to the time signals generated by the deep brain population may be expected to affect the cortical population. In other embodiments, the two types of electromagnetic signals can be simultaneous. In still further embodiments, the two types of signals can be varied in other manners, for example, five minutes of deep brain signals alternating (and in some cases, at least partially overlapping) with five or some other number of minutes of cortical signals; or generally continuous deep brain stimulation in association with theta-burst or aperiodic cortical stimulation.
In other cases, deep brain stimulation can be combined with cortical stimulation in other manners. For example, deep brain stimulation can provide the primary electromagnetic treatment for a patient suffering from Parkinson's Disease, and can be provided on a continuous, nearly continuous, or generally continuous basis (e.g., 24/7 or at least during typical waking hours). Cortical stimulation can be provided simultaneously with the deep brain stimulation (and/or during interstices in the deep brain stimulation) to (a) facilitate or effectuate neuroplastic changes, (b) develop functionality that compensates at least in part for one or more patient symptoms, and/or (c) improve neuropsychological, neuropsychiatric, sensory, and/or motor functionality. Accordingly, the cortical stimulation can be provided at subthreshold levels, possibly in association with an appropriate adjunctive therapy program. In some embodiments, the cortical stimulation may comprise suprathreshold pulses or bursts.
In the foregoing manner, the addition of cortical stimulation to a regimen that typically employs deep brain stimulation may enhance patient functionality, in some instances at least in part because signaling changes associated with a cortical neural population may over time at least partially compensate for neurologic dysfunction associated with a deep brain population. In other cases, the reverse may apply, e.g., deep brain stimulation may enhance/expand upon an increase in functionality attainable from cortical stimulation alone.
In another aspect of an embodiment shown in
Plasticity may occur at several levels following spinal cord injury, including plasticity involving the cerebral cortex, brain stem, spinal cord, and peripheral nervous system. By providing electromagnetic signals to particular neuroanatomical sites associated with neuroplasticity, either individually or in combination, overall neuroplasticity may increase and/or be enhanced and therefore may facilitate the patient's recovery from a spinal cord injury. Appropriate stimulation sites may be identified in one or more manners described above, for example, through a neurofunctional localization procedure involving EEG or fMRI to characterize or identify particular types of neural activity (e.g., neural activity associated with neurofunctional change or recovery following neurologic damage), and/or a neurostructural identification procedure such as DTI to locate particular neural tracts or projections (e.g., neural tracts that remain viable following such damage, and which may be expected to successfully carry neural signals to facilitate or effectuate neuroplastic change).
The combination of cortical stimulation and cranial (e.g., vagal) and/or other peripheral nerve stimulation may enhance neural stimulation efficacy beyond that of either of such modes individually. Vagal nerve stimulation may affect cerebral blood flow or alter neural activity in various cortical and/or subcortical regions, including the orbitofrontal cortex, the somatosensory cortex, the insular cortices, the thalamus, the hypothalamus, the amygdala, the cingluate gyrus, and other regions (Jeong-Ho Chae et al., “A review of the new minimally invasive brain stimulation techniques in psychiatry,” Rev. Bras. Psiquiatr., Vol. 23 No. 2, Sao Paulo, June 2001). Accordingly, the combination of cortical stimulation and cranial nerve stimulation (e.g., in a sequential, partially overlapping, or simultaneous manner) may aid the establishment or maintenance of a desired neural outcome (e.g., a metabolic shift away from a hypometabolic or hypermetabolic state; or a modulation of a maladaptive neuroplastic condition). The combination of cortical stimulation and cranial nerve stimulation, possibly in association with one or more adjunctive therapies, may alternatively or additionally enhance the restoration and/or development of neural function (e.g., in patients suffering from neurologic damage or other neurologic dysfunction).
The identification of particular brain regions that exhibit acute or chronic changes in neural activity or neural metabolite levels as a result of cranial or other peripheral nerve stimulation may aid in (a) identifying one or more sites at which to implant cortical electrodes, (b) determining particular cortical regions to which stimulation signals should be directed across different time periods, (c) establishing or adjusting cortical and/or peripheral stimulation parameters (e.g., current or voltage levels, signal polarity), or (d) establishing or adjusting one or more adjunctive therapies. Such brain regions may be identified, for example, using a neurofunctional localization procedure (e.g., fMRI) to measure neural activity levels before, during, and/or after one or more cranial nerve stimulation periods, either independent of or in conjunction with patient performance or attempted performance of one or more relevant neurofunctional activities or tasks.
The combination of cortical stimulation and vagal or other cranial nerve stimulation may reduce certain symptoms associated with neuropsychiatric disorders (e.g., depression or anxiety), movement disorders, auditory disorders (e.g., tinnitus or auditory hallucinations), or other conditions. The benefits that may be achieved with the combination of cortical stimulation and cranial nerve stimulation may be similar or analogous to those achieved with deep brain stimulation alone or the combination of deep brain stimulation and cortical stimulation. Because both cortical stimulation and vagal stimulation are each significantly less invasive than deep brain stimulation, their combination may provide a favorable alternative to deep brain stimulation alone or deep brain stimulation in combination with cortical stimulation.
In other embodiments, other combinations of signal delivery devices are possible. For example, such combinations can include the combination of a transcranial magnetic stimulation device with a transcranial direct current stimulation device. The selection of a particular system and/or signal delivery device can be based at least in part on the type, extent, or severity of the patient's neurologic dysfunction, and/or the patient's amenability to particular signal delivery devices.
The signal delivery device 1050c receives electrical pulses from the external signal source 1074c, which can in turn include a power supply, controller, pulse generator, and pulse transmitter. The external signal source 1074c can also include a plug 1071 having a needle 1073 and a plurality of contacts arranged on the needle to contact the internal contacts in the socket 1058. In operation, the needle 1073 is inserted into the socket 1058 to engage the contacts on the needle with the contacts on the socket, and then the signal source 1074c is activated to transmit electrical pulses to the electrodes 1051.
The signal delivery device 1050d can receive electrical pulses from an external signal source 1074d. For example, the external signal source 1074d can be electrically coupled to the signal delivery device 1050d by a lead line 1059 that passes through a hole 1039 in the skull 544. In another embodiment, the signal delivery device 1050d can be coupled to an integrated pulse system and external control portion generally similar to the pulse systems and control portions described above with reference to
The ETD 1176 can include a conventional adhesive patch electrode commonly used for providing an electrical coupling to a particular location on a patient. The signal delivery device 1150 can include a head 1180 coupled to a shaft 1181. The head 1180 and shaft 1181 may be integrally formed of an electrically conductive material forming a conductive core 1182 that forms an electrical energy conduit. The conductive core 1182 may extend throughout a portion or along the entire length of the signal delivery device 1150. The conductive core 1182 may be carried by or encased in an electrically insulating material or cladding 1183. The conductive core 1182 may extend from an upper or proximal contact surface 1184a to a lower or distal contact surface 1184b. Contact surfaces 1184a and 1184b provide a signal exchange interface of the conductive core 1182. In one embodiment, the signal delivery device 1150 includes a distal contact surface 1184b that operates as a single electrode, and which may be positioned epidurally or subdurally. In other embodiments, the signal delivery device 1150 can include multiple contacts or electrode elements that may be coupled to a single potential or power channel, or to individual potentials or power channels. An electromagnetic signal return path may be provided by one or more additional signal delivery devices 1150 (which may be positioned proximate to or remote from a stimulation site), and/or another ETD 1176 in a manner understood by those skilled in the art. The ETD 1176 can include an energy transfer patch 1185 that may have several layers. In general, an ETD 1176 can include an outer flexible, insulating, and/or articulated layer 1186, an electrically conductive layer 1187, and a gel layer 1188. The conductive layer 1187 may include a conductive material (e.g., aluminum) for carrying or conveying an electrical signal. The conductive layer 814 may be appropriately shaped (e.g., oval or elliptical) for conforming to a portion of the skull's rounded surface.
One feature of an embodiment of the signal delivery device 1250a described above with reference to
In another embodiment shown in
In other embodiments, the signal delivery devices 1250a, 1250b can have arrangements other than those described above. For example, other signal delivery devices can have support members with shapes other than those shown in
In one aspect of embodiments described above with reference to
Although the signal delivery device 1350 of the illustrated embodiment includes a 2×3 electrode array (i.e., 2 rows of 3 electrodes each), in other embodiments, electrode assemblies in accordance with the present invention can include more or fewer electrodes in other types of symmetrical and asymmetrical arrays. For example, in one other embodiment, such a signal delivery device 1350 can include a 2×1 electrode array. In another embodiment, such a signal delivery device can include a 2×5 electrode array. In a further embodiment, such a signal delivery device can include a single electrode for unipolar stimulation.
The signal delivery device 1350 can include one or more coupling apertures 1355 extending through the periphery of the support member 1352. The coupling apertures 1355 can facilitate attachment of the signal delivery device to the dura mater at, or at least proximate to, a stimulation site. The signal delivery device 1350 can also include a protective sleeve 1378 disposed over a portion of the cable 1377 to protect the cable 1377 from abrasion resulting from contact with the edge of an access hole formed in the patient's skull.
The gimbal fitting 1590 is configured to allow an operator greater control over the placement of an electrically conductive tip 1591 of the conductive member 1551. In use, the tip 1591 of the conductive member 1551 will be threaded through an opening in the gimbal fitting 1590. By pivoting the gimbal fitting 1590 with respect to the threaded shaft 1581, the angular orientation of the conductive member 1551 with respect to a pilot hole 1531 in the skull 544 can be accurately controlled. Once the operator determines that the conductive member 1551 is at the appropriate angle, e.g., using a surgical navigation system, the operator may advance the conductive member 1551 to position the conductive tip 1591 at a target site. Once the tip 1591 is in position, a capped lead 1559 may be press-fitted on the head 1580 of the device 1550. This will crimp the proximal length of the connective member 1551 between the head 1580 and the conductive inner surface of the cap, providing an effective electrical connection between the conductive member 1551 and the lead 1559. In other embodiments, the signal delivery device 1550 can have other configurations suitable for deep brain stimulation. Such devices are available from Medtronic, Inc. of Minneapolis, Minn..
In still further embodiments, the electromagnetic stimulation may be applied to neural tissue other than cortical or deep brain tissue. For example,
From the foregoing, it will be appreciated that specific embodiments of the invention have been described herein for purposes of illustration, but that various modifications may be made without deviating from the invention. For example, many of the techniques described above in the context of cortical stimulation from within the skull can also be applied to cranial nerves (e.g., the vagal nerve) that may be accessible without entry directly through the patient's skull. Many of the techniques described above in the context of subthreshold stimulation may be applied as well in the context of superthreshold stimulation. Aspects of the invention described in the context of two time periods may apply to more time periods (e.g., three or more) in other embodiments. Electromagnetic signals described in some embodiments as stimulation signals may be replaced with inhibitory signals in other embodiments, for example, by changing signal frequency and/or other signal delivery parameters. Aspects of the invention described in the context of particular embodiments may be combined or eliminated in other embodiments. For example, many of the signal delivery devices described above may have other configurations and/or capabilities in other embodiments. Several of those embodiments are described in the following pending U.S. Applications, all of which are incorporated herein by reference: Ser. No. 10/606,202, filed Jun. 24, 2003; 10/410,526, filed Apr. 8, 2003; 10/731,892, filed Dec. 9, 2003; 10/742,579, filed Dec. 18, 2003; and Ser. No. 10/891,834, filed Jul. 15, 2004. Further, while advantages associated with certain embodiments of the invention have been described in the context of those embodiments, other embodiments may also exhibit such advantages, and not all embodiments need necessarily exhibit such advantages to fall within the scope of the invention. Accordingly, the invention is not limited except as by the appended claims.