Abstract: In some examples of selecting a target therapy delivery site for treating a patient condition, a relatively high frequency electrical stimulation signal is delivered to at least two areas within a first region (e.g., an anterior nucleus of the thalamus) of a brain of a patient, and changes in brain activity (e.g., as indicated by bioelectrical brain signals) within a second region (e.g., a hippocampus) of the brain of the patient in response to the delivered stimulation are determined. The target therapy delivery site, an electrode combination, or both, may be selected based on the changes in brain activity.

Abstract: Deep Brain Stimulation (DBS) electrodes are positioned within (or adjacent to) white matter fiber tracts in a brain of patient. The DBS electrodes may be positioned near one or more stimulation sites within the white matter fiber tracts. The stimulation sites may be selected based on the disorder of the patient. In some examples, the stimulation sites may be selected based on one or more symptoms of the patient. In some examples, additional electrodes may be positioned in another area to collect bioelectrical brain signals. The area in which the additional electrodes are placed is an area that is different from the stimulation site but is targeted by stimulation therapy provided at the stimulation site.

Abstract: A system for closed-loop therapy includes memory configured to store a first set of one or more parameters for a first set of therapeutic electrical stimulation signals. The system includes processing circuitry configured to determine one or more local field potential (LFP) measurements of an LFP that is intrinsically generated, cause stimulation generation circuitry to deliver one or more electrical stimulation signals, determine one or more evoked resonant neural activity (ERNA) signals that are evoked by delivery of respective ones of the electrical stimulation signals, determine a second set of one or more parameters for a second set of therapeutic electrical stimulation signals based on the one or more evoked signals and the one or more LFP measurements, and cause the stimulation generation circuitry to deliver the second set of the one or more therapeutic electrical stimulation signals.

Abstract: A system includes memory and processing circuitry coupled to the memory and configured to determine a plurality of local field potential (LFP) measurements of an LFP, wherein the LFP is intrinsically generated by a signal source within a brain of a patient, determine one or more electrodes for delivering a therapeutic electrical stimulation signal based on the LFP measurements, control stimulation generation circuitry to deliver a plurality of electrical stimulation signals via the determined one or more electrodes, wherein the plurality of electrical stimulation signals each comprise at least one different therapy parameter, for respective ones of the plurality of electrical stimulation signals, determine respective evoked signals, wherein the respective evoked signals are evoked by delivery of the respective plurality of electrical stimulation signals, and determine at least one parameter for the therapeutic electrical stimulation signal based on the respective evoked signals.

Abstract: Various embodiments concern delivering electrical stimulation to the brain at a plurality of different levels of a stimulation parameter and sensing a bioelectrical response of the brain to delivery of the electrical stimulation for each of the plurality of different levels of the stimulation parameter. A suppression window of the stimulation parameter can be identified as having a suppression threshold as a lower boundary and an after-discharge threshold as an upper boundary based on the sensed bioelectrical responses. A therapy level of the stimulation parameter can be set for therapy delivery based on the suppression window. The therapy level of the stimulation parameter may be set closer to the suppression threshold than the after-discharge threshold within the suppression window. Data for hippocampal stimulation demonstrating a suppression window is presented.

Abstract: In some examples of selecting a target therapy delivery site for treating a patient condition, a relatively high frequency electrical stimulation signal is delivered to at least two areas within a first region (e.g., an anterior nucleus of the thalamus) of a brain of a patient, and changes in brain activity (e.g., as indicated by bioelectrical brain signals) within a second region (e.g., a hippocampus) of the brain of the patient in response to the delivered stimulation are determined. The target therapy delivery site, an electrode combination, or both, may be selected based on the changes in brain activity.

Abstract: In some examples of selecting a target therapy delivery site for treating a patient condition, a relatively high frequency electrical stimulation signal is delivered to at least two areas within a first region (e.g., an anterior nucleus of the thalamus) of a brain of a patient, and changes in brain activity (e.g., as indicated by bioelectrical brain signals) within a second region (e.g., a hippocampus) of the brain of the patient in response to the delivered stimulation are determined. The target therapy delivery site, an electrode combination, or both, may be selected based on the changes in brain activity.

Abstract: Deep Brain Stimulation (DBS) electrodes are positioned within (or adjacent to) white matter fiber tracts in a brain of patient. The DBS electrodes may be positioned near one or more stimulation sites within the white matter fiber tracts. The stimulation sites may be selected based on the disorder of the patient. In some examples, the stimulation sites may be selected based on one or more symptoms of the patient. In some examples, additional electrodes may be positioned in another area to collect bioelectrical brain signals. The area in which the additional electrodes are placed is an area that is different from the stimulation site but is targeted by stimulation therapy provided at the stimulation site.

Abstract: Various embodiments concern delivering electrical stimulation to the brain at a plurality of different levels of a stimulation parameter and sensing a bioelectrical response of the brain to delivery of the electrical stimulation for each of the plurality of different levels of the stimulation parameter. A suppression window of the stimulation parameter can be identified as having a suppression threshold as a lower boundary and an after-discharge threshold as an upper boundary based on the sensed bioelectrical responses. A therapy level of the stimulation parameter can be set for therapy delivery based on the suppression window. The therapy level of the stimulation parameter may be set closer to the suppression threshold than the after-discharge threshold within the suppression window. Data for hippocampal stimulation demonstrating a suppression window is presented.

Abstract: Deep Brain Stimulation (DBS) electrodes are positioned within (or adjacent to) white matter fiber tracts in a brain of patient. The DBS electrodes may be positioned near one or more stimulation sites within the white matter fiber tracts. The stimulation sites may be selected based on the disorder of the patient. In some examples, the stimulation sites may be selected based on one or more symptoms of the patient. In some examples, additional electrodes may be positioned in another area to collect bioelectrical brain signals. The area in which the additional electrodes are placed is an area that is different from the stimulation site but is targeted by stimulation therapy provided at the stimulation site.

Abstract: Various embodiments concern delivering electrical stimulation to the brain at a plurality of different levels of a stimulation parameter and sensing a bioelectrical response of the brain to delivery of the electrical stimulation for each of the plurality of different levels of the stimulation parameter. A suppression window of the stimulation parameter can be identified as having a suppression threshold as a lower boundary and an after-discharge threshold as an upper boundary based on the sensed bioelectrical responses. A therapy level of the stimulation parameter can be set for therapy delivery based on the suppression window. The therapy level of the stimulation parameter may be set closer to the suppression threshold than the after-discharge threshold within the suppression window. Data for hippocampal stimulation demonstrating a suppression window is presented.

Abstract: A characteristic of a washout period following the delivery of therapy to a patient according to a therapy program may be determined based on a physiological parameter of the patient. A washout period includes the period of time during which a carryover effect from the therapy delivery dissipates. Monitoring a washout period may be useful for timing the delivery of therapy according to different therapy programs during a therapy evaluation period. For example, at least one physiological signal of the patient may be monitored to automatically determine when a washout period has ended, e.g., when stimulation and carryover effects of therapy delivery according to a first therapy program have substantially dissipated, in order to determine when therapy delivery according to a second therapy program can be initiated.

Abstract: Techniques, systems, and devices are disclosed for delivering stimulation therapy to a patient. In one example, a medical device senses, via one or more electrodes, one or more oscillations of a bioelectrical signal of a brain of a patient. In response to sensing the one or more oscillations, the medical device generates a plurality of bursts of stimulation therapy pulses, the plurality of bursts comprising an inter-burst frequency selected based on a frequency of the one or more oscillations of the bioelectrical signal. Further, the medical device delivers the plurality of bursts of stimulation therapy pulses to the patient to modulate a state of the patient associated with the one or more oscillations of the bioelectrical signal.

Abstract: In some examples of selecting a target therapy delivery site for treating a patient condition, a relatively high frequency electrical stimulation signal is delivered to at least two areas within a first region (e.g., an anterior nucleus of the thalamus) of a brain of a patient, and changes in brain activity (e.g., as indicated by bioelectrical brain signals) within a second region (e.g., a hippocampus) of the brain of the patient in response to the delivered stimulation are determined. The target therapy delivery site, an electrode combination, or both, may be selected based on the changes in brain activity.

Abstract: Deep Brain Stimulation (DBS) electrodes are positioned within (or adjacent to) white matter fiber tracts in a brain of patient. The DBS electrodes may be positioned near one or more stimulation sites within the white matter fiber tracts. The stimulation sites may be selected based on the disorder of the patient. In some examples, the stimulation sites may be selected based on one or more symptoms of the patient. In some examples, additional electrodes may be positioned in another area to collect bioelectrical brain signals. The area in which the additional electrodes are placed is an area that is different from the stimulation site but is targeted by stimulation therapy provided at the stimulation site.

Abstract: Deep Brain Stimulation (DBS) electrodes are positioned within (or adjacent to) white matter fiber tracts in a brain of patient. The DBS electrodes may be positioned near one or more stimulation sites within the white matter fiber tracts. The stimulation sites may be selected based on the disorder of the patient. In some examples, the stimulation sites may be selected based on one or more symptoms of the patient. In some examples, additional electrodes may be positioned in another area to collect bioelectrical brain signals. The area in which the additional electrodes are placed is an area that is different from the stimulation site but is targeted by stimulation therapy provided at the stimulation site.

Abstract: In some examples of selecting a target therapy delivery site for treating a patient condition, a relatively high frequency electrical stimulation signal is delivered to at least two areas within a first region (e.g., an anterior nucleus of the thalamus) of a brain of a patient, and changes in brain activity (e.g., as indicated by bioelectrical brain signals) within a second region (e.g., a hippocampus) of the brain of the patient in response to the delivered stimulation are determined. The target therapy delivery site, an electrode combination, or both, may be selected based on the changes in brain activity.

Abstract: Various embodiments concern delivering electrical stimulation to the brain at a plurality of different levels of a stimulation parameter and sensing a bioelectrical response of the brain to delivery of the electrical stimulation for each of the plurality of different levels of the stimulation parameter. A suppression window of the stimulation parameter can be identified as having a suppression threshold as a lower boundary and an after-discharge threshold as an upper boundary based on the sensed bioelectrical responses. A therapy level of the stimulation parameter can be set for therapy delivery based on the suppression window. The therapy level of the stimulation parameter may be set closer to the suppression threshold than the after-discharge threshold within the suppression window. Data for hippocampal stimulation demonstrating a suppression window is presented.

Abstract: Techniques for varying stimulus parameters used in neural stimulation to improve therapy efficacy, minimize energy consumption, minimize undesired side effects, and minimize loss of therapeutic effectiveness due to physiologic tolerance to stimulation. Neural stimulation is provided having a stimulation amplitude, a stimulation frequency, a stimulation pulse duration, an electrode-firing pattern, and a set of electrode-firing-polarity conditions. At least one of the stimulation parameters is pseudo-randomly varied. A second stimulation parameter is changed based upon having pseudo-randomly varied the first stimulation parameter and based upon a predetermined relationship specifying how changes in the first parameter affect desirable values for the second parameter.

Abstract: Various embodiments concern delivering electrical stimulation to the brain at a plurality of different levels of a stimulation parameter and sensing a bioelectrical response of the brain to delivery of the electrical stimulation for each of the plurality of different levels of the stimulation parameter. A suppression window of the stimulation parameter can be identified as having a suppression threshold as a lower boundary and an after-discharge threshold as an upper boundary based on the sensed bioelectrical responses. A therapy level of the stimulation parameter can be set for therapy delivery based on the suppression window. The therapy level of the stimulation parameter may be set closer to the suppression threshold than the after-discharge threshold within the suppression window. Data for hippocampal stimulation demonstrating a suppression window is presented.