In some embodiments, a clinician programmer device for controlling a deep brain stimulation (DBS) system is adapted to assist a clinician to conduct an electrode screening review for the DBS system including screening of segmented electrodes. The clinician programmer stores software code for conducting a screening review in memory. The software code may comprise: code for providing one or more interface screens for guiding the user of the device through testing of electrode configurations of the implantable stimulation lead, wherein the code for providing applies at least one testing progression for guiding the user of the device through a defined testing order.

An implantable medical device (IMD) includes a memory configured to store a set of therapy parameters for subsensory electrical stimulation of a patient; and therapy delivery circuitry configured to deliver the subsensory electrical stimulation to at least one of a sacral nerve or tibial nerve based on the stored set of therapy parameters to provide immediate therapeutic effect caused by the ongoing delivery of the subsensory electrical stimulation to address incontinence, wherein a stimulation intensity of the subsensory electrical stimulation is less than 80% of a stimulation intensity at a sensory threshold, and wherein the patient does not perceive delivery of the subsensory electrical stimulation and perceives delivery of stimulation at the sensory threshold.

An example of a system for delivering neurostimulation energy may include a programming control circuit and a user interface. The programming control circuit may be configured to generate stimulation parameters according to a neurostimulation program including a pattern of interferential stimulation configured to effect asynchronous and/or non-regular activation of nerve fibers by simultaneously delivering a first stimulation current having a first waveform with a first frequency using a first electrode configuration and a second stimulation current having a second waveform with a second frequency using a second electrode configuration. The user interface may be configured to determine the neurostimulation program and to provide the pattern of interferential stimulation with modulation of the first waveform, the second waveform, the first electrode configuration, and/or the second electrode configuration to result in a time-varying beat frequency capable of effecting the asynchronous and/or non-regular activation of the nerve fibers.

A system can utilize interleaving periods or waveforms to stimulate patient tissue and sense signals using the stimulation electrodes. For example, the system can utilize alternating therapeutic periods and sensing periods. As another example, the system can alternate between biphasic waveforms having opposite temporal orders of positive and negative phases. As another example, waveforms that differ in a parameter, such as amplitude or pulse width, can be interleaved to provide different information in the respective sensed signals.

Techniques are disclosed for implementing the use of electrically evoked compound action potentials (ECAPs) to adaptively adjust parameters of high frequency electrical stimulation. In one example, a medical device delivers electrical stimulation therapy comprising a train of electrical stimulation pulses to a patient, wherein the train of electrical stimulation pulses comprises a pulse frequency greater than or equal to 500 Hertz. After delivering the train of electrical stimulation pulses, the medical device ceases delivery of the high frequency electrical stimulation therapy for a predetermined period of time. During the predetermined period of time, the medical device senses an ECAP from the patient and determines, based on the sensed ECAP, a value of a parameter at least partially defining the train of electrical stimulation pulses. Responsive to the predetermined period of time elapsing, the medical device resumes delivery of the high frequency electrical stimulation according to the determined parameter.

Methods and systems for providing sub-perception spinal cord stimulation are described. In some examples, the stimulation current is shared among three or more anodes and three or more cathodes to provide virtual poles that are configured to cover a relatively large area of the patient's neural tissue that contains the “sweet spot” for treating the patient's pain. Covering a relatively large area mitigates the need to perform time-intensive sweet spot searching. In some examples, one or more stimulation parameters are varied while the stimulation is being provided.

A neuromodulation system and method of providing sub-threshold modulation therapy. Electrical modulation energy is delivered to a target tissue site of the patient at a programmed intensity value, thereby providing therapy to a patient without perception of stimulation. In response to an event, electrical modulation energy is delivered at incrementally increasing intensity values. At least one evoked compound action potential (eCAP) is sensed in a population of neurons at the target tissue site of the patient in response to the delivery of the electrical modulation energy at the incrementally increasing intensity values. One of the incrementally increased intensity values is selected based on the sensed eCAP(s). A decreased intensity value is automatically computed as a function of the selected intensity value. Electrical modulation energy is delivered to the target tissue site of the patient at the computed intensity value, thereby providing sub-threshold therapy to the patient.

Methods and systems for programming stimulation parameters for an implantable medical device for neuromodulation, such as spinal cord stimulation (SCS) are disclosed. The stimulation parameters define user-configured waveforms having at least a first phase having a first polarity and a second phase having a second polarity, wherein the first and second phases are separated by an interphase interval (IPI). By delivering user-configured waveforms with different IPIs, stimulation geometry, and other waveform settings, therapeutic asynchronous activation of dorsal column fibers can be obtained.

Graphical User Interface (GUI) control of a stimulator device is disclosed. The GUI receives modeling information indicating optimal stimulation parameters for a patient based on patient testing, and may also receive an indication of a particular stimulation mode to be used for the patient which comprises a subset of those parameters. The GUI provides simple options to allow a user to navigate the optimal parameters or subsets to constrain selection to only those stimulation parameters set within the optimal parameters or subsets.

Methods and systems for proving spinal cord stimulation (SCS) for treating pain in a patient are described. Embodiments of the described methods and systems can provide sub-perception SCS that has a fast wash-in time by using stimulation parameters that activate surround inhibition in the patient. Measuring retrograde potentials evoked by the stimulation can be performed to facilitate choosing the best stimulation parameters, in particular, the best stimulating electrode contact configurations for activating surround inhibition. For example, peripheral electrodes may be placed at the center of the patient's pain (within a local receptive field (LRF), with respect to the patient's pain center) and within an area surrounding the patient's pain center (within a surrounding receptive field (SRF), with respect to the patient's pain center). Retrograde evoked potentials measured and the SRF and/or the LRF can be used to guide the selection of the stimulation parameters.