An electrical stimulation system and method for the treatment of neurological disorders is disclosed. In a preferred embodiment, the electrical stimulation system includes channels of electrodes positioned in electrical contact with tissue of a neuromuscular target body region of a patient to provide pattered neuromuscular stimulation to the patient's musculature. In addition, at least one electrode from a channel is positioned in electrical contact with a tissue of the motor control region of the brain. A series of patterned electrical pulses are then applied to the patient through the channels to provide peripheral neuromuscular stimulation, and a direct current is applied transcranially to the brain. Various exemplary embodiments of the invention are disclosed.

This invention relates generally to systems and methods for multifocal direct brain stimulation to enhance cognitive processing, such as but not limited to stimulation-induced modulation of memory.

The present invention relates to a closed loop computer brain interface device for an individual comprising a receiver module configured to obtain at least one sensor signal indicative of a movement or action of the individual, a processing module operably connected to the receiver module and configured to determine at least one neuronal feedback signal based at least in part on the obtained sensor signal and a transmitter module operably connected to the processing module and configured to transmit the determined neuronal feedback signal to a neurostimulation device of the individual or a neurostimulation module operably connected to the processing module, wherein the neuronal feedback signal is configured to elicit a sensory percept in the cortex of the individual via stimulating afferent sensory axons of the central nervous system targeting sensory neurons of the cortex of the individual and wherein the elicited sensory percept indicates movement support information related to the obtained sensor signal to support the execution of the movement or action of the individual.

The present invention further relates to a computer program comprising instructions for implementing a closed loop computer brain interface device when being executed by signal processing and transceiver modules of a signal and data processing device, a neuronal stimulation device or system.

A system for treating a patient comprises a stimulator for stimulating brain tissue, a controller for setting stimulation parameters and a diagnostic tool for measuring patient parameters and producing diagnostic data. The stimulation parameters comprise test stimulation parameters and treatment stimulation parameters. The stimulator delivers test stimulation energy to the brain tissue based on at least one test stimulation parameter and delivers treatment stimulation energy to the brain tissue based on at least one treatment stimulation parameter. One or more treatment stimulator parameters are determined based on the diagnostic data produced by the diagnostic tool The system is constructed and arranged to treat a neurological disease or a neurological disorder. Methods of treating a neurological disease or neurological disorder are also provided.

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.

An implantable electrode array is provided, the electrode array comprising a substrate, the substrate having a front side and a back side, and a first number of first electrodes. The first electrodes are formed as contact pads, and are arranged on the front side. The substrate comprises a second number of prefabricated holes at predetermined positions, the holes extending from the front side through the substrate towards the back side, and being arranged such the holes may be penetrated by elongated electrodes placed at the predetermined positions.

Disclosed are methods and systems for optimized deep or superficial deep-brain stimulation using multiple therapeutic modalities impacting one or multiple points in a neural circuit to produce Long-Term Potentiation (LTP) or Long-Term Depression (LTD). Also disclosed are methods for treatment of clinical conditions and obtaining physiological impacts. Also disclosed are: methods and systems for Guided Feedback control of non-invasive deep brain or superficial neuromodulation; patterned neuromodulation, ancillary stimulation, treatment planning, focused shaped or steered ultrasound; methods and systems using intersecting ultrasound beams; non-invasive ultrasound-neuromodulation techniques to control the permeability of the blood-brain barrier; non-invasive neuromodulation of the spinal cord by ultrasound energy; methods and systems for non-invasive neuromodulation using ultrasound for evaluating the feasibility of neuromodulation treatment using non-ultrasound/ultrasound modalities; neuromodulation of the whole head, treatment of multiple conditions, and method and systems for neuromodulation using ultrasound delivered in sessions.

A medical lead with at least a distal portion thereof implantable in the brain of a patient is described, together with methods and systems for using the lead. The lead is provided with at least two sensing modalities (e.g., two or more sensing modalities for measurements of field potential measurements, neuronal single unit activity, neuronal multi unit activity, optical blood volume, optical blood oxygenation, voltammetry and rheoencephalography). Acquisition of measurements and the lead components and other components for accomplishing a measurement in each modality are also described as are various applications for the multimodal brain sensing lead.

A method of stimulating a patient's brain comprising delivering an electrical stimulation to at least one electrode causing stimulation of a person's anterior cingulum bundle, or especially causing stimulation of a person's dorsal portion of an anterior cingulum bundle resulting in emotional change(s) in a patient comprising one or more of the following: anxiolysis, mirth, analgesia, improved affective tone, enhanced cognitive focus, increased well-being, engagement, or optimism. Further embodiments contemplate an apparatus. Further embodiments contemplate two implanted electrodes within the dorsal portion of the anterior cingulum bundle spaced between about 5 mm and 8 mm apart, having electrical stimulation parameters of between about 1.0 mA and about 3.5 mA, between about 100 Hz to about 150 Hz, and having a pulse width of between about 100 microseconds to about 200 microseconds.

Various methods for making probe devices that include the addition of electrode contact material using various different processes and/or techniques, along with the resulting devices. Some methods include adding electrode contact material such that the resulting electrode contacts are suitable for direct contact with patient tissue while encapsulating materials that are not.