Techniques are disclosed related to increasing prior limits imposed on MR gradient switching speed (dB/dt) without causing significant discomfort or severe pain perception to patients. The technique disclosed herein do so by modifying the pulsing gradient fields that are ordinarily available for MR imaging protocols. Doing so stimulates the peripheral nerves and thus enables a quick, reversible, and complete inhibition of action potential propagation through the stimulated region of tissue, referred to as a nerve conduction block.

A gastric electric stimulation (GES) system is disclosed which includes a processing system, and at least one of a left vagus nerve sensor (L/R Sensors) and a right vagus nerve sensor coupled to the processing system, the processing system is configured to receive a model which statistically correlates sensed compound nerve action potential (CNAP) parameters measured from at least one of left and right vagus nerves of subjects within a population to feedback surveys of the subjects corresponding to a plurality of gastric symptoms and symptom parameters, receive one or more gastric symptoms of a subject outside of the population (Subject.sub.out), determine CNAP parameters that correspond to the gastric symptoms with least severity (CNAP.sub.min), measure CNAP activity of the Subject.sub.out from the L/R sensors while modifying GES parameters for the Subject.sub.out, select the GES parameters that corresponds to the CNAP.sub.min (GES.sub.out), and output the GES.sub.out.

A stimulation system includes an energy source, an electronics unit with a controller, and an actuator that is coupled with the electronics unit and/or the energy source. The actuator emits electromagnetic waves for stimulation of genetically manipulated tissue. The electronics unit is disposed in a housing. The stimulation system is configured for at least temporary implantation in a human or animal body. The controller controls the stimulation of tissue in the body by way of the electromagnetic waves emitted by the actuator. A selector of the stimulation system selects the area of the said tissue for stimulation. The selector includes a masking device for masking certain areas of the tissue, so that an intensity of the stimulation for the masked areas is reduced or equal to zero.

An example of a neurostimulation system may include a stimulation output circuit to deliver the neurostimulation, a sensing circuit to sense a signal indicative of a response to the neurostimulation, and a stimulation control circuit to control the delivery of the neurostimulation using stimulation parameters. The stimulation control circuit may include a response detector and a steering module. The response detector may be configured to detect signal feature(s) from the sensed signal and to determine a response parameter indicative of an intensity of the response to the neurostimulation using the detected signal feature(s). The steering module may be configured to receive user commands for moving a stimulation field and to adjust the stimulation parameters to move the stimulation field according to the user commands while maintaining a value of the response parameter between thresholds.

Spinal cord stimulation (SCS) system having a recharging system with self alignment, a system for mapping current fields using a completely wireless system, multiple independent electrode stimulation outsource, and control through software on a Smartphone/mobile device and tablet hardware during trial and permanent implants. SCS system can include multiple electrodes, multiple, independently programmable, stimulation channels within an implantable pulse generator (IPG) providing concurrent, but unique stimulation fields. SCS system can include a replenishable power source, rechargeable using transcutaneous power transmissions between antenna coil pairs. An external charger unit, having its own rechargeable battery, can charge the IPG replenishable power source. A real-time clock can provide an auto-run schedule for daily stimulation. A bi-directional telemetry link informs the patient or clinician the status of the system, including the state of charge of the IPG battery. Other processing circuitry in current IPG allows electrode impedance measurements to be made.

Devices and methods for blocking signal transmission through neural tissue. One step of a method includes placing a therapy delivery device into electrical communication with the neural tissue. The therapy delivery device includes an electrode contact having a high charge capacity material. A multi-phase direct current (DC) can be applied to the neural tissue without damaging the neural tissue. The multi-phase DC includes a cathodic DC phase and anodic DC phase that collectively produce a neural block and reduce the charge delivered by the therapy delivery device. The DC delivery can be combined with high frequency alternating current (HFAC) block to produce a system that provides effective, safe, long term block without inducing an onset response.

This document discusses, among other things, systems and methods to provide a paresthesia therapy to a patient using an implantable neuromodulation system, wherein providing the paresthesia therapy may include delivering to the patient an electrical waveform having a duration and a distribution of frequencies in the range of 0.001 kHz to 20 kHz, wherein the distribution of frequencies includes a first frequency group of one or more frequencies and a second frequency group of one or more frequencies, and wherein the patient continuously experiences paresthesia throughout the duration of the electrical waveform.

Systems and methods for treating a patient's pain using ramped therapeutic signals for modulating inhibitory interneurons, and associated systems and methods are disclosed. A representative method for treating a patient includes positioning an implantable signal delivery device proximate to a target location at or near the patient's spinal cord, and delivering an electrical therapy signal to the target location via the implantable signal delivery device, wherein the electrical therapy signal has a frequency in a frequency range of from about 1 kHz to about 100 kHz, and wherein the frequency is increased or decreased from a first value to a second value during delivery.

The present disclosure is directed to a system and method for selectively and reversibly modulating targeted neural and non-neural tissue of a nervous system for the treatment of pain. An electrical stimulation is delivered to the treatment site that selectively and reversibly modulates the targeted neural- and non-neural tissue of the nervous structure, inhibiting the perception of pain while preserving other sensory and motor function, and proprioception.

An electrical stimulation system includes at least one electrical stimulation lead, each of the at least one electrical stimulation lead including a plurality of stimulation electrodes; and a processor coupled to the lead and configured to perform actions, including: directing delivery of at least one electrical pulse through at least one of the stimulation electrodes of the at least one electrical stimulation lead to tissue of a patient; and directing discrete or intermittent measurement of an electrical characteristic of the tissue using at least one of the stimulation electrodes of the at least one electrical stimulation lead during, and after, delivery of the at least one electrical pulse to the tissue of the patient.