Abstract: A computer implemented system and method facilitates a cycle of generation, sharing, and refinement of volumes related to stimulation of anatomical tissue, such as brain or spinal cord stimulation. Such volumes can include target stimulation volumes, side effect volumes, and volumes of estimated activation. A computer system and method also facilitates analysis of groups of volumes, including analysis of differences and/or commonalities between different groups of volumes.

Abstract: Systems and methods for determining a rotational orientation of a lead for use in electrostimulation of a body tissue are disclosed. A system may receive image data of at least a portion of the lead including image data of a marker configured to identify a rotational orientation of the lead. The system may receive at least one template of the lead having a specified rotational orientation. Each template may include a reference data cube and a reference marker direction vector. The system may generate a target data cube of the marker using the image data of the marker, and register the reference data cube to the target data cube to produce a transformation operator. The system may estimate the rotational orientation of the lead using the reference marker direction vector and the determined transformation operator.

Abstract: A computer implemented system and method facilitates a cycle of generation, sharing, and refinement of volumes related to stimulation of anatomical tissue, such as brain or spinal cord stimulation. Such volumes can include target stimulation volumes, side effect volumes, and volumes of estimated activation. A computer system and method also facilitates analysis of groups of volumes, including analysis of differences and/or commonalities between different groups of volumes.

Abstract: An example of a system for programming a neurostimulator may include a storage device and a pattern generator. The storage device may store a pattern library and one or more neuronal network models. The pattern library may include fields and waveforms of neuromodulation. The one or more neuronal network models may each be configured to allow for evaluating effects of one or more fields in combination with one or more waveforms in treating one or more indications for neuromodulation. The one or more neuronal network models may include a first pain model configured to allow for optimization of neurostimulation using paresthesia, the second pain model configured to allow optimization of neurostimulation using anatomy. The pattern generator may be configured to construct and approximately optimize a spatio-temporal pattern of neurostimulation and/or its building blocks using at least one or more of the first pain model or the second pain model.

Abstract: Incorrect connection or mapping of leads' proximal terminals to the ports of an Implantable Stimulator Device (ISD), such as an implantable pulse generator or an external trial stimulator, is a concern, and this disclosure is directed to use of measurement and identification algorithms to either determine that leads are properly connected to their assigned ISD ports, or to determine which leads are connected to the ports even if the leads are not preassigned to the ports. Particular focus is given in the disclosed technique to assessing leads that comprise larger number of electrodes than are supported at each port, and thus have more than one proximal terminal that connect to more than one port of the ISD.

Abstract: A system for programming electrical stimulation by a lead includes a processor coupled to a display. The processor presents an interface on the display with user-selectable controls to define stimulation fields and repeating stimulation patterns for delivering the stimulation fields temporally-coordinated with each other. The user-selectable controls include a field control to define the number of stimulation fields, a location control to define locations of the stimulation fields relative to the lead, a repetition control to define a repetition frequency of the stimulation patterns, and a temporal-adjustment control to define temporal adjustments of the stimulation fields.

Abstract: An example of a system for programming a neurostimulator may include a storage device and a pattern generator. The storage device may store a pattern library and one or more neuronal network models. The pattern library may include fields and waveforms of neuromodulation. The one or more neuronal network models may each be configured to allow for evaluating effects of one or more fields in combination with one or more waveforms in treating one or more indications for neuromodulation. The pattern generator may be configured to construct and approximately optimize a spatio-temporal pattern of neurostimulation and/or its building blocks using at least one neuronal network model.

Abstract: A method and system include a processor that outputs a characterization of a correspondence between a volume of estimated tissue activation and a target and/or side effect stimulation volume, and/or that provides controls by which to modify thresholds and/or amounts according to which the volume of estimated activation is to correspond to the target volume.

Abstract: Methods and systems for electrical stimulation can include obtaining a biosignal of the patient; altering at least one stimulation parameter of an electrical stimulation system in response to the biosignal; and delivering an electrical stimulation current to one or more selected electrodes of the electrical stimulation system using the at least one stimulation parameter. In some embodiments, a power spectrum is determined from the biosignal. In some embodiments, the biosignal is at least two different biosignals measured at the same or different locations on the patient and a coherence, correlation, or association between the two biosignal is determined.

Abstract: An example of a system for programming a neurostimulator may include a storage device and a pattern generator. The storage device may store a pattern library and one or more neuronal network models. The pattern library may include fields and waveforms of neuromodulation. The one or more neuronal network models may each be configured to allow for evaluating effects of one or more fields in combination with one or more waveforms in treating one or more indications for neuromodulation. The pattern generator may be configured to construct and approximately optimize a spatio-temporal pattern of neurostimulation and/or its building blocks using at least one neuronal network model. The spatio-temporal pattern of neurostimulation may include a series of sub-patterns for treating an indication of the one or more indications for neuromodulation.

Abstract: Various manners are disclosed in which neurostimulation can be programmed to provide stimulation pulses designed to alter the level of synchronization in a target neural tissue, as is useful in Deep Brain Stimulation (DBS) therapy for example. Stimulation pulses are issued in pulse packets, with one or more variations added within or between pulse packets, such as variations in pulse width, amplitude, frequency, or shape. Such variations afford greater ability to differentially recruit sub-populations of neural tissue in both space and time. Such pulse packets may be issued from one or more electrodes, which pulse packets may or may not overlap in time.

Abstract: Methods and systems for electrical stimulation can include obtaining a biosignal of the patient; altering at least one stimulation parameter of an electrical stimulation system in response to the biosignal; and delivering an electrical stimulation current to one or more selected electrodes of the electrical stimulation system using the at least one stimulation parameter. In some embodiments, a power spectrum is determined from the biosignal. In some embodiments, the biosignal is at least two different biosignals measured at the same or different locations on the patient and a coherence, correlation, or association between the two biosignal is determined.

Abstract: A method for identifying a rotational orientation of a lead includes obtaining a radiological image of the lead having a lead body, a distal tip, electrodes, and an asymmetric marker, where the lead defines a lead axis along the portion of the lead extending from the distal tip and including the electrodes and the asymmetric marker; determining, using the set of lead slices and the set of marker slices, a direction vector extending from an estimated lead axis and passing through a determined center of weighted mass of the lead; and providing an indication of a direction of the direction vector on a display.

Abstract: This document discusses a medical device for coupling to a plurality of implantable electrodes. The medical device includes a therapy circuit, a biomarker sensing circuit, and a control circuit operatively coupled to the therapy circuit and biomarker sensing circuit. The therapy circuit delivers electrical neurostimulation energy to the plurality of implantable electrodes. The biomarker sensing circuit generates a sensed biomarker signal representative of a physiological biomarker of a subject. The control circuit initiates delivery of bursts of pulses of the electrical neurostimulation energy to the plurality of the implantable electrodes according to a first therapy regimen and monitor efficacy of the delivered electrical neurostimulation energy using the sensed biomarker signal; and changes the electrical neurostimulation to a second therapy regimen upon detecting a reduction in the efficacy of the first therapy regimen using the sensed biomarker signal.

Abstract: A method and system for identifying a rotational orientation of an implanted electrical stimulation lead utilize radiological images of the lead. The lead has an asymmetric marker with a longitudinal band extending around a portion of the circumference of the lead. The method and system includes obtaining radiological images of the lead; generating an isosurface image from the radiological images and displaying the isosurface image on a display device, where the isosurface image comprises an image of the longitudinal band of the marker; identifying a bulge in the isosurface image corresponding the longitudinal band of the marker; and determining a rotational orientation of the lead based on the rotational orientation of the bulge in the isosurface image.

Abstract: This document discusses medical device for coupling to a plurality of implantable electrodes. The medical device includes a therapy circuit configured to deliver electrical neurostimulation energy to the plurality of implantable electrodes; and a control circuit operatively coupled to the therapy circuit. The control circuit is configured to: initiate delivery of bursts of pulses of the electrical neurostimulation energy to the plurality of the implantable electrodes, wherein pulses within a burst include an intra-pulse period; change a combination of electrodes used to deliver the bursts of pulses according to an inter-burst period between bursts; and change the inter-burst period during the delivery of the electrical neuromodulation energy.

Abstract: An electrical stimulation system includes an implantable control module configured and arranged for implantation in a body of a patient. The implantable control module includes a processor that generates and delivers electrical stimulation pulses or pulse bursts at a pathological frequency or with a temporal separation between pulses or pulse bursts individually selected based on a pre-determined distribution function based on a pre-selected pathological frequency.

Abstract: Methods and systems for electrical stimulation can include obtaining a biosignal of the patient; altering at least one stimulation parameter of an electrical stimulation system in response to the biosignal; and delivering an electrical stimulation current to one or more selected electrodes of the electrical stimulation system using the at least one stimulation parameter. In some embodiments, a power spectrum is determined from the biosignal. In some embodiments, the biosignal is at least two different biosignals measured at the same or different locations on the patient and a coherence, correlation, or association between the two biosignal is determined.

Abstract: A system for identifying potential portions of a body in which electrical stimulation to treat a condition or disorder affects at least one symptom of the condition or disorder, stimulation effect, or side effect performs the following acts: obtaining, for each of multiple stimulation instances, an estimation of a region of the body stimulated during the stimulation instance and a score for each of at least one symptom, stimulation effect, or stimulation side effect; and determining, for each of multiple portions of the body using the scores and the estimates in a permutation test, a likelihood that stimulation of that portion of the body affects at least one symptom, stimulation effect, or stimulation side effect. In other embodiments, the system sets up a relationship between the outcomes of stimulation and influence of a particular part of the body on the outcome, and derives this influence using a pseudoinverse.

Abstract: A method and system for identifying a rotational orientation of an implanted electrical stimulation lead utilize radiological images of the lead. The lead has an asymmetric marker with a longitudinal band extending around a portion of the circumference of the lead. The method and system includes obtaining radiological images of the lead and using those images to determine a predicted rotational orientation of the lead. The predicted rotational orientation of the lead is then corrected based on at least one parameter of the imaging technique used to generate the image data.