Electromagnetic stimulation for treating diseases, conditions associated with diseases and/or inhibiting pain with reduced side effects and associated systems and methods are disclosed. In particular embodiments, high-frequency stimulation in the range of from about 1.5 kHz to about 100 kHz may be applied to a patient's target tissue region to treat the disease, associated condition and/or to inhibit pain. Electrical stimulation in accordance with similar parameters can directly affect a cellular membrane, such as a neuron and in particular, a spontaneously active neuron and/or a quiescent neuron.

An example of a system for delivering neurostimulation energy to a patient using a plurality of electrodes may include a stimulation circuit and a sensing circuit. The stimulation circuit may be configured to deliver the neurostimulation energy using stimulation electrodes selected from the plurality of electrodes and to control the delivery of the neurostimulation energy. The sensing circuit may be configured to receive one or more neural signals from sensing electrodes selected from the plurality of electrodes and may include a signal processing circuit. The signal processing circuit may include a detection circuit and an analysis circuit. The detection circuit may be configured to detect one or more attributes of neural responses from the received one or more neural signals. The analysis circuit may be configured to analyze the detected one or more attributes of the neural responses for one or more indications of a neurodegenerative disease.

Systems and methods for stimulating tissue. Exemplary embodiments include systems and methods configured to maintain one electrode at a fixed voltage potential and switching a second electrode between different fixed voltage potentials.

Provided is an effective stereognosis training system that integrates hardware and software to provide a simple, reliable, quantitative system to provide tactile rehabilitation and progress monitoring. The system can include an interactive device including a novel set of objects, that are combined with neuromodulatory systems such as wireless closed-loop vagus nerve stimulation to improve neural plasticity and expedite functional recovery. The system can send updates to therapists or clinicians to monitor progress and encourage compliance with prescribed therapy.

An example device for repairing a tissue is described herein. The device can include a flexible carrier layer, and a support member including a plurality of micro-protrusions extending therefrom. The support member can be at least partially integrated with the flexible carrier layer. Additionally, the flexible carrier layer can be configured to cover at least a portion of the tissue, and the micro-protrusions can be configured to mechanically interface with the tissue.

An adaptive cognitive prosthetic that learns to replace neural function that was lost due to a brain injury or disease is described herein. In some embodiments, an adaptive cognitive prosthetic comprises a processing unit for converting input data from an input assembly into a cognitive variable and selecting a stimulation pattern for conveying the cognitive variable. The processing unit employs an adaptive algorithm to assemble the stimulation pattern by combination of subset stimulation patterns, the combination of subset stimulation patterns learned by the adaptive algorithm through error analysis.

Methods and related systems for modulating neural activity by cyclically modulating neural activity in peripheral neural structures are disclosed. Neural activity may be modulated cyclically by stimuli delivered via various types of stimulus sources. In an aspect, activity of a sensory nerve is modulated. Neural modulation may be used, for example, to modulate an undesired sensation, such as pain, or an immune or inflammatory response or process. Delivery of stimuli for modulating neural activity may be controlled in part in response to an input from a user input device.

An embodiment in accordance with the present invention is directed to a system and device for applying electrical direct current transcranially to the brain that is combined with a behavioral activity consisting of an isometric force production task. The device is non-invasive or implantable and serves to improve motor symptoms in Parkinson's disease (PD) and other movement disorders. During the stimulation, the patient is engaged in a behavioral task using a system consisting of two force transducers and a controller. The patient holds the transducers, one in each hand, and is engaged in a task that requires the brain to assign forces to each arm so that the sum of the forces matches an instructed amount. In an electrode placement specifically for PD, bilateral primary motor cortices are simultaneously stimulated according to a specific algorithm that depends on the forces that the PD affected individual produces in the behavioral task.

A method for providing electrical stimulation to a user, the method comprising: providing an electrical stimulation device, in communication with a controller, at a head region of the user; with the electrical stimulation device, providing a stimulation treatment having a waveform configured for neuromodulation in the user; with the controller, performing an adjustment to the stimulation treatment, wherein performing the adjustment includes: generating a transformed waveform with application of a transfer function to the waveform, wherein the transfer function scales the waveform and selectively attenuates extreme waveform values while maintaining a frequency characteristic of the waveform in the transformed waveform; and applying the transformed waveform with the electrical stimulation device, thereby modulating the stimulation treatment.

Systems and methods are provided for stimulating the brain of a patient to treat a medical condition. In some aspects, a method includes positioning a stimulating device comprising electrical contacts configured to electrically stimulate locations associated with a patient's brain, and initiating a rehabilitation process to include the patient performing a task. The method also includes acquiring feedback from the patient at least while the patient is performing the task, generating, based on the acquired feedback, electrical stimulations to treat the medical condition of the patient. In some aspects, the method further includes generating a report indicative of a patient performance.