This invention concerns a system for brain signal measurement and analysis using graphene based electrodes. The system is minimally invasive with small size electrodes and a stamp-size electronic processor with wireless communication and a remote computing device, enabling brain signal collection outside of clinical settings. The electrodes and electronic processor are both imprinted onto the subject's scalp using three-dimensional printers with small size electronics. After use, the electrodes and electronic processor may be washed off or removed without injuries to the subject.

Provided herein are neural interface systems for a patient, the systems comprising an implantable sensor device and an external processing device. The implantable sensor device comprises: an implantable lead assembly for implantation above the skull and below the skin of the patient, and for recording physiologic parameter information of the patient; and an implantable transmitter for receiving the physiologic parameter information from the implantable lead assembly and for transmitting patient data that is based on the physiologic parameter information. The external processing device receives the patient data from the implantable transmitter. Methods of provided a neural interface are also described.

Provided herein are neural interface systems for a patient, the systems comprising an implantable sensor device and an external processing device. The implantable sensor device comprises: an implantable lead assembly for implantation above the skull and below the skin of the patient, and for recording physiologic parameter information of the patient; and an implantable transmitter for receiving the physiologic parameter information from the implantable lead assembly and for transmitting patient data that is based on the physiologic parameter information. The external processing device receives the patient data from the implantable transmitter. Methods of provided a neural interface are also described.

A cortical access system for delivering a medical tool into an epidural and/or subdural space and onto a patient's brain tissue through a cranium opening comprises: a turret including a proximal end portion, a distal end portion, and a first channel extending from an entrance opening to an exit opening, the first channel configured to guide the medical tool from the entrance opening to the exit opening for positioning on the patients brain tissue. The medical tool may be an electrode or an endoscope.

A cortical access system for delivering a medical tool into an epidural and/or subdural space and onto a patient's brain tissue through a cranium opening comprises: a turret including a proximal end portion, a distal end portion, and a first channel extending from an entrance opening to an exit opening, the first channel configured to guide the medical tool from the entrance opening to the exit opening for positioning on the patients brain tissue. The medical tool may be an electrode or an endoscope.

A method for resilience training, including: exposing a healthy human subject to one or more stress-evoking perturbations selected to affect activation of deeply located limbic areas; instructing the healthy human subject to perform in a timed relation to the exposing, at least one activity configured to selectively affect activation of said deeply located limbic areas; recording EEG signals from the healthy human subject during the exposing; analyzing the recorded EEG signals to identify at least one EEG signature indicating an activation level of the deeply located limbic areas; determining an activation level of the deeply located limbic areas based on the identified at least one EEG signature; delivering a human-detectable indication to the healthy human subject according to the determined activation level.

A method for resilience training, including: exposing a healthy human subject to one or more stress-evoking perturbations selected to affect activation of deeply located limbic areas; instructing the healthy human subject to perform in a timed relation to the exposing, at least one activity configured to selectively affect activation of said deeply located limbic areas; recording EEG signals from the healthy human subject during the exposing; analyzing the recorded EEG signals to identify at least one EEG signature indicating an activation level of the deeply located limbic areas; determining an activation level of the deeply located limbic areas based on the identified at least one EEG signature; delivering a human-detectable indication to the healthy human subject according to the determined activation level.

Disclosed is a patch guide method including acquiring a 3-dimensional scan model including the head of an object by using a depth camera, by a computer, acquiring a 3-dimensional brain MRI model of the object, matching the scan model and the brain MRI model to acquire a matched model, acquiring an image captured by photographing the head of the object by using the depth camera, and matching one location of the captured image and one location on the matched model.

The present invention provides a non-physical communication interface between humans and machines which allows for specific commands with a high degree of success. Systems and methods provided for herein allow for a non-physical, non-verbal and non-audible communication interface between humans and machines, or a telepathic communication from a human to a computing device. Embodiments of the invention allow for human telepathic control of machines, or allow for human to human telepathic communication through the use of one or more computers or machines.

The present invention provides a non-physical communication interface between humans and machines which allows for specific commands with a high degree of success. Systems and methods provided for herein allow for a non-physical, non-verbal and non-audible communication interface between humans and machines, or a telepathic communication from a human to a computing device. Embodiments of the invention allow for human telepathic control of machines, or allow for human to human telepathic communication through the use of one or more computers or machines.