Presented herein are techniques for stimulating a balance prosthesis recipient based on one or more motion signals and a classification of the type of activity in which the recipient is currently participating. More specifically, a balance prosthesis system is configured to monitor the motion of at least part of a recipient's body and to determine an activity classification for the recipient (e.g., determine the “class” or “category” of the recipient's real-time motion). The recipient's motion and the activity classification are used to generate stimulation signals for delivery to the recipient.

Disclosed are various examples and embodiments of systems, devices, components and methods configured to rehabilitate or strengthen one or more muscles in a patient, and to reduce pain sensed by the patient, through a unique combination of electrical stimulation signals delivered to one or more target peripheral nerves. Medical electrical lead(s) comprising electrode(s) are positioned adjacent to, in contact with, or in operative positional relationship to, one or more target peripheral nerves of the patient. The target peripheral nerves typically comprise motor and sensory nerves. In one embodiment, first stimulation signals having a first range of frequencies are delivered through the electrode(s) to the target nerves to rehabilitate muscles enervated by the motor nerves. Second stimulation signals having a second range of frequencies are delivered through the electrode(s) to the target nerves to provide pain relief to the patient. The first range of frequencies is lower than the second range of frequencies.

An example of a system includes a blood pressure modulation device and a controller. The blood pressure modulation device may be configured to deliver a therapy to chronically maintain blood pressure within a prescribed range. The blood pressure modulation device may include a neuromodulator configured to deliver neuromodulation energy to neural tissue in a spinal cord or near the spinal cord using a first parameter set. The controller may include analyzer circuitry configured to determine an actual or anticipated blood pressure demand event indicated for a blood pressure change, and therapy parameter adjuster circuitry configured to respond to the actual or anticipated blood pressure demand event by delivering neuromodulation energy using a second parameter set to change the blood pressure.

The invention relates to a system for preventing and/or reducing muscle spasms and improving postural stability in a patient suffering from muscle spasm and postural instability. The system comprises an electrode configured to be positioned to stimulate a target dorsal root ganglion associated with the muscle spasm and postural instability. The system also comprises a pulse generator provided with an output port connectable to the electrode. The pulse generator includes a processor configured to generate an electric stimulation signal at the electrode while connected. Here, the electric stimulation signal stimulates the dorsal root ganglion with an electric pulse while so positioned. Further, the system comprises a user interface configured to set at least one user-specified parameter of the electric pulse.

The disclosure concerns a method for the treatment of cervical dystonia, comprising inserting a stimulation device into the brain of a patient, the stimulation device being configured to provide electrical stimulation to affect first and second stimulation targets within the brain. The first stimulation target is the subthalamic nucleus (STN); and the second stimulation target is the ventral intermediate nucleus (VIM), or the ventralis oralis posterior thalamus (VOP), or both the ventral intermediate nucleus (VIM) and the ventralis oralis posterior thalamus (VOP).

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 pain while preserving other sensory and motor function, and proprioception.

A system for adjusting neuromodulation parameters used by a neuromodulator operably connected to a plurality of electrodes to modulate a neural target, may comprise a translation trigger detector configured to determine that a translation trigger has occurred, a first parameter setting storage configured to store first parameter settings for use by the neuromodulator to modulate the neural target, and a neuromodulation parameter translator. The neuromodulation parameter translator may be operably connected to the translation trigger detector to automatically translate the first parameter settings into a second parameter settings in response to determining the translation trigger has occurred, and replace the first parameter settings with the second parameter settings, or store the second parameter settings in a second parameter setting storage. Automatically translating may include either automatically translating from cathodic parameter settings to anodic parameter settings, or automatically translating from anodic parameter settings to cathodic parameter settings.

An implantable medical device is configured to receive an input that specifies a time domain allocation between two or more stored stimulation programs and to provide control signals corresponding to each of the two or more stimulation programs to stimulation circuitry to interleave the two or more stimulation programs in time according to the input. The time domain allocation may set a proportion of time during which each of the stimulation programs is active during repeating epochs. The time domain allocation may be set by a user to transition between configured stimulation programs or to specify stimulation that is based on two or more different stimulation programs. The time domain allocation may also be adjusted automatically to optimize an indication of an effectiveness of stimulation that is provided by the patient.

This disclosure is directed to devices, systems, and techniques for controlling electrical stimulation. In some examples, a system includes a user interface and processing circuitry. The processing circuitry is configured to output, for display by the user interface, a message requesting the patient perform a set of actions, receive, from the user interface, user input indicative of a patient response associated with the set of actions, and determine, based on the user input, one or more adjustments to a control policy which controls electrical stimulation delivered by a medical device based on a plurality of evoked compound action potentials (ECAPs) sensed by the medical device.

A method for optimization of the stimulation pattern of a set of implanted electrodes in excitable tissue of a patient is disclosed, wherein it comprises the steps of: (a) choosing a first group of a certain number of from said set of implanted electrodes, (b) stimulating the excitable tissue electrically by said first group of electrodes, (c) registering information provided by the patient, (d) assigning each electrode of said first group of electrodes a value related to said information, wherein these steps are repeated for one or more further groups of said certain number of electrodes chosen from said set of implanted electrodes, wherein each electrode may be included in one or several groups, wherein the total assigned value for each electrode is calculated, and wherein electrodes having a total assigned value exceeding a predetermined value or a predetermined number of the electrodes having the highest total assigned value are chosen to be included in said stimulation pattern, as well as a method for treatment or alleviation of a disease or condition by use of a set of electrodes whose stimulation pattern has been optimized with said method, and a system for optimization of the stimulation pattern.