A device and algorithm for controlling an autonomic function in an individual. A controller device that utilizes physiological measurements (such as blood pressure) to regulate spinal cord electrical stimulation to stabilize blood pressure. A control interface and algorithm for controlling an autonomic function in a subject. For instance, an algorithm that utilizes physiological measurements (such as blood pressure) to regulate spinal cord electrical stimulation to stabilize blood pressure.

In various embodiments a method of synergistically using a neuromodulation stimulator and a robotic exoskeleton for the restoration of voluntary movement and greater muscle activation in chronically paralyzed subjects is provided. The noninvasive neuromodulation system delivers signals to facilitate the restoration and/or enhancement of neurological function where at least one effect is strengthened stepping capacity that can be further substantiated when coupled with robotic exoskeleton assistance.

Described are systems and methods for preventing, diagnosing, and/or treating one or more medical conditions. The medical conditions can be ocular and/or neurological diseases, disorders, and/or conditions. The systems and methods can employ a microstimulator that is configured to be placed within an anatomical structure of a subject. The microstimulator can be capacitively linked to an external electronic device to provide neuromodulation to a biological target site proximal to the anatomical structure. The microstimulator can include a body and an electrically conductive insert arranged within the body to create a capacitively coupled link with the external electronic device. The electrically conductive insert can receive a power signal from an external electronic device and convert the power signal to deliver a therapy signal to the biological target site.

Disclosed herein are systems and methods for nerve conduction block. The systems and methods can utilize at least one rechargeable electrode. The methods can include delivering a first direct current with a first polarity to an electrode proximate nervous tissue sufficient to at least partially block conduction in the nervous tissue.

The exemplified systems and methods facilitate a nerve conduction block at a target nerve using electrical stimulation applied from one or more electrodes located on a percutaneous lead that are placed in parallel, or substantially in parallel, and without direct contact, to a long axis of the peripheral nerve over an overlapping nerve region of greater than about 3 millimeters. The exemplified system and method can be further configured to block nerve condition without eliciting onset activity and co-excitation of non-targeted structures. The exemplified method and system can be performed using conventional percutaneous leads, though an improved percutaneous lead design is disclosed herein. In an aspect, an introducer is disclosed that facilitates accurate and consistent insertion of the percutaneous lead to the specified or intended position relative to the target nerve. In another aspect, a treatment kit comprising the various system components to treat pain is disclosed.

A neuromodulation system is provided herein. The system can include a neuromodulation device, an electronics package, which can be part of the neuromodulation device; an external controller; a sensor; and a computing device. The neuromodulation device can include a neuromodulation lead having a lead body configured to be bent to a desired shape and to maintain that shape in order to position the electrodes relative to neural and/or muscular structures when fully deployed. The neuromodulation device can also include an antenna including an upper and a lower coil electrically connected to each other in parallel. The computing device can execute a closed-loop algorithm based on physiological sensed data relating to sleep.

Certain embodiments described herein relate to a system for use in analyzing neural activity of nerves surrounding a biological lumen. The system includes a probe body, electrodes, a stimulator, and an amplifier. The stimulator delivers electrical stimulation via a first pair of the electrodes, supported by the probe body, to test for an evoked neural response by nerves surrounding the biological lumen. The amplifier includes a pair of input terminals, an output terminal, and a ground reference terminal. A second pair of the electrodes is electrically coupled to the pair of input terminals of the amplifier, to thereby enable the amplifier to produce the sensed signal indicative of the evoked neural response. A remaining one of the electrodes, which is not included in the first and the second pairs of the electrodes, is electrically coupled to the ground reference terminal of the amplifier.

Generally discussed herein are systems, devices, and methods for providing a therapy (e.g., stimulation) and/or data signal using an implantable device. Systems, devices and methods for interacting with (e.g., communicating with, receiving power from) an external device are also provided.

This document provides methods and materials for modulating afferent nerve signals to treat medical conditions such as CHF, CHF respiration, dyspnea, peripheral vascular disease (e.g., peripheral arterial disease or venous insufficiency), hypertension (e.g., age-associated hypertension, resistant hypertension, or chronic refractory hypertension), COPD, sleep apnea, and chronic forms of lung disease where muscle dysfunction is a part of the disease pathophysiology. For example, methods and materials involved in using electrical and/or chemical techniques to block or reduce afferent nerve signals (e.g., nerve signals of group III and/or IV afferents coming from skeletal muscle and/or the kidneys) are provided.

Techniques to help improve efficiency or effectiveness of treating a disorder such as RLS or PLMD, such as by issuing neural electrostimulations to a particular patient, while varying one or more amplitude parameters (e.g., at least one of electrostimulation current amplitude, electrostimulation voltage amplitude, or electrostimulation pulsewidth duration). A corresponding patient-subjective or patient-objective response can be observed. A characteristic electrostimulation intensity relationship can be generated, for example, based on the determined respective at least one of RLS or PLMD response indication threshold amplitude parameters and the plurality of corresponding neural electrostimulation durations. Once this characteristic electrostimulation intensity relationship has been generated, it can then be used to control issuing subsequent neural electrostimulations to the particular patient according to (1) at least one goal and (2) a variable operating point based upon the generated characteristic electrostimulation intensity relationship.