An example of a system for delivering neurostimulation using a stimulation device and controlling the delivery of the neurostimulation may include a programming control circuit and a stimulation control circuit. The programming control circuit may be configured to program the stimulation device for delivering the neurostimulation according to a pattern of neurostimulation pulses defined by one or more stimulation waveforms. The stimulation control circuit may be configured to determine the pattern of neurostimulation pulses with the one or more stimulation waveforms constrained by one or more thresholds, and may include threshold circuitry that may be configured to receive one or more known values of the one or more thresholds and to determine needed values of the one or more thresholds by executing an algorithm allowing for prediction of the needed values of the one or more thresholds based on the one or more known values.

A method of using deep brain stimulation (DBS) for treating mental disorders associated with high connectivity in brain circuits, such as cortico-striato-thalamo-cortical (CSTC) circuits, is provided. The method comprises providing a first electrical signal having a first frequency to a first electrode implanted at a first location within a brain circuit and providing a second electrical signal having a second frequency to a second electrode implanted at a second location within the brain circuit. The first frequency and the second frequency are unequal.

A system and method are provided that include a power supply having positive and negative terminals. The negative terminal defines a reference ground. First and second electrodes are positioned within a patient and configured to be located proximate to tissue of interest that is associated with a target region. A control circuit is configured to control delivery of current for a therapy between the first and second electrodes. A current regulator (CR) circuit is connected to, and configured to control current flow through, at least the first electrode during delivery of the therapy under direction of the control circuit. A floating power supply is connected across power supply terminals of the CR circuit. The CR circuit and floating power supply are coupled to a floating ground node that is electrically separate from the reference ground.

Epidural electrical stimulation (EES) systems and techniques for accessing and locating targeted spinal cord segments are disclosed. In some examples, a method includes providing a first set of electrodes of an EES system at a first set of locations on the dura mater of a spine of a mammal, the first set of locations on the dura mater corresponding to a first muscle group of the mammal; providing a second set of electrodes of the epidural electrical stimulation system at a second set of locations on the dura mater of the spine of the mammal, the second set of locations on the dura mater corresponding to a second muscle group of the mammal; and stimulating the first and second sets of locations on the dura mater by electrically energizing the first and second sets of electrodes, respectively, thereby activating the first and second muscle groups in a coordinated manner.

Techniques are described, for medical devices that deliver electrical stimulation using current or voltage regulators having an adjustable master amplitude. One example method includes receiving, via a programmer for an electrical stimulator, user input indicating a desired electrical current amplitude, and selecting a first fraction adjustment or a second fraction adjustment, as a target adjustment for achieving the desired electrical current amplitude.

Systems and methods for enhancing muscle function of skeletal muscles in connection with a planned spine surgery intervention in a patient's back are provided. The method includes implanting one or more electrodes in or adjacent to tissue associated with one or more skeletal muscles within a back of a patient, the one or more electrodes in electrical communication with a pulse generator programmed for enhancing muscle function of the one or more skeletal muscles. Electrical stimulation is delivered, according to the programming during a time period associated with the planned spine surgery intervention, from the pulse generator to the tissue associated with the one or more skeletal muscles via the one or more electrodes, thereby improving neuromuscular control system performance of the one or more spine stabilizing muscles in connection with the planned spine surgery intervention to reduce the patient's recovery time associated with the planned spine surgery intervention.

Systems and methods for deep brain stimulation using beta burst feedback in accordance with embodiments of the invention are illustrated. One embodiment includes a deep brain stimulation system, including a neurostimulator, and a controller, where the controller is communicatively coupled to the neurostimulator and configured to obtain a plurality of neural activity signals from the neurostimulator, identify beta bursts within each neural activity signal, classify identified beta bursts as pathological or normal, and modify stimulation provided by the neurostimulator based on the classified beta bursts.

Implantable electrodes with power delivery wearable for treating sleep apnea, and associated systems and methods are disclosed herein. A representative system includes non-implantable signal generator worn by the patient and having an antenna that directs a mid-field RF power signal to an implanted electrode. The implanted electrode in turn directs a lowerfrequency signal to a neural target, for example, the patient's hypoglossal nerve. Representative signal generators can have the form of a mouthpiece, a collar or other wearable, and/or a skin-mounted patch.

Selective high-frequency spinal cord modulation for inhibiting pain with reduced side effects and associated systems and methods are disclosed. In particular embodiments, high-frequency modulation in the range of from about 1.5 KHz to about 50 KHz may be applied to the patient's spinal cord region from an epidural, cervical location to address at least one of high back pain, mid-back pain, low back pain, and leg pain without creating paresthesia in the patient.

Systems and methods are provided for delivering neurostimulation therapies to patients for treating chronic heart failure. A titration process is used to gradually increase the stimulation intensity to a desired therapeutic level. This titration process can minimize the amount of time required to complete titration so as to begin delivery of the stimulation at therapeutically desirable levels.