Restless Leg Syndrome (RLS) or Periodic Limb Movement Disorder (PLMD) can be treated using high frequency (HF) electrostimulation. This can include selecting or receiving a subject presenting with RLS or PLMD. At least one electrostimulation electrode can be located at a location associated with at least one of, or at least one branch of, a sural nerve, a peroneal nerve, or a femoral nerve. HF electrostimulation can be delivered to the subject, which can include delivering subsensory, subthreshold, AC electrostimulation at a frequency that exceeds 500 Hz and is less than 15,000 Hz to the location to help reduce or alleviate the one or more symptoms associated with RLS or PLMD. A charge-balanced controlled-current HF electrostimulation waveform can be used.

According to an embodiment of a method for providing neural stimulation, activity is sensed, and neural stimulation is automatically controlled based on the sensed activity. An embodiment determines periods of rest and periods of exercise using the sensed activity, and applies neural stimulation during rest and withdrawing neural stimulation during exercise. Other embodiments are provided herein.

Methods and systems for detecting if a stimulation lead implanted in a patient's brain has moved. Lead movement occurring between a first time and a second time may be determined by comparing features extracted from evoked potentials recorded at the two times. The disclosed methods and systems are particularly useful for determining if a stimulation lead has moved between the time it was implanted in the patient's brain and the time that stimulation parameters are being optimized. Lead movement during implantation, during parameter optimization, and during or between other lead optimization processes may be determined as well.

In one embodiment, an implantable pulse generator (IPG) for providing a neurostimulation therapy, comprises: pulse generation circuitry and pulse delivery circuitry for controlling generation and delivery of electrical pulses to a patient using one or more electrodes of a stimulation lead; measurement circuitry for determining characteristics of one or more electrodes selected for delivery of electrical pulses; and a processor for controlling the IPG according to executable code; wherein the IPG is adapted to calculate values for an impedance model of the one or more selected electrodes using the determined plurality of voltage measurements and to adjust current levels for the exponentially decreasing current pattern based on the calculated values for the impedance mode.

A method of surgically positioning an electrode array at a desired implantation location relative to a nerve. A temporary probe electrode is temporarily positioned adjacent to the nerve and at a location which is caudorostrally separate to the desired implantation location of the electrode array. The implanted position of the probe electrode is temporarily fixed relative to the nerve. During implantation of the electrode array, electrical stimuli are applied from one of the temporarily fixed probe electrode and the electrode array, to evoke compound action potentials on the nerve. Compound action potentials evoked by the stimuli are sensed from at least one electrode of the other of the temporarily fixed probe electrode and the electrode array. From the sensed compound action potentials a position of the electrode array relative to the nerve is determined.

An apparatus includes an implantable stimulator to treat sleep disordered breathing (SDB) and at least one electrode associated with the stimulator. The apparatus includes a therapy device arranged to be implanted within a head/neck region of a patient. The therapy device includes a microstimulator including a housing to encapsulate at least stimulation circuitry, a rechargeable power element, and a control portion including a therapy manager to control the stimulation circuitry.

An apparatus external to a patient and communicatively coupled to an implant within the patient is disclosed. The apparatus identifies a tentative stimulation parameter adjustment constraint and an absolute stimulation parameter adjustment constraint for a stimulation parameter associated with the implant. The apparatus also determines an impedance of an electrode implanted within the patient and coupled with the implant. Based on the impedance of the electrode, the apparatus automatically adjusts the stimulation parameter within a range between a present value and a first value defined by the tentative stimulation parameter adjustment constraint. Additionally, based on user input manually provided by the patient, the apparatus further adjusts the stimulation parameter within a range between the first value and a second value beyond the first value and defined by the absolute stimulation parameter adjustment constraint. Corresponding apparatuses, systems, and methods are also disclosed.

Stimulation of neural activity in a nerve supplying the spleen, wherein the nerve is adjacent to the splenic artery at a position where the splenic artery is not in direct contact with the pancreas, can modulate pro- and anti-inflammatory molecules levels, thereby reducing inflammation and providing ways of treating disorders, such as disorders associated with inflammation. The invention provides improved ways of reducing inflammation with minimized off-target effects, in particular surgical trauma.

Disclosed is an implantable device for controllably delivering a neural stimulus. The device comprises: a plurality of electrodes including one or more stimulus electrodes and one or more sense electrodes; a stimulus source configured to provide a neural stimulus to be delivered via the one or more stimulus electrodes to a neural pathway of a patient in order to evoke a neural response on the neural pathway; measurement circuitry configured to process a signal window sensed at the one or more sense electrodes subsequent to the delivered neural stimulus, the sensed signal window including an evoked neural response; and a control unit. The control unit is configured to: control the stimulus source to provide the neural stimulus according to a stimulus parameter; estimate, using a detector, a location of the evoked neural response within the sensed signal window; determine, based on the location of the evoked neural response within the sensed signal window, whether truncation of the evoked neural response by the sensed signal window is occurring; and mitigate, based on the determination, the truncation of the evoked neural response.

Stimulation of neural activity in a nerve supplying the spleen, wherein the nerve is adjacent to the splenic artery at a position where the splenic artery is not in direct contact with the pancreas, can modulate pro- and anti-inflammatory molecules levels, thereby reducing inflammation and providing ways of treating disorders, such as disorders associated with inflammation. The invention provides improved ways of reducing inflammation with minimized off-target effects, in particular surgical trauma.