A computer-implemented neuro-chemical and neuro-circuitry conditioning training method that employs specially programmed computing devices and systems that guides a user through a process to discover, extract, describe, and synthesize their inner dream (or dreams) and interacts with a user in order to design their dream as they have imagined it. Through the assets, environment, and other such deliverables generated from the various method modules along with specially programed computing devices, the user is enabled to interact with the assets and the generated environment and replay those interactions on-demand thereby effecting neuro-chemical and neuro-circuitry training.

A method of replicating a mental state of a first subject in a second subject comprising: capturing a mental state of the first subject represented by brain activity patterns; and replicating the mental state of the first subject in the second subject by inducing the brain activity patterns in the second subject.

The present invention provides systems, methods, and articles for stress reduction and sleep promotion. A stress reduction and sleep promotion system includes at least one remote device, at least one body sensor, and at least one remote server. In other embodiments, the stress reduction and sleep promotion system includes machine learning.

The invention relates to a device for neurovascular stimulation, at least comprising: at least one brain activity sensor, at least one cardiovascular sensor, at least one computing unit and at least one output unit. The computing unit comprises at least one task algorithm, wherein signals of at least the brain activity sensor and the cardiovascular sensor can be received by the computing unit, and wherein a task, which is in correlation with at least the signals from at least the brain activity sensor and the signals of the cardiovascular sensor, can be determined by means of the task algorithm and can be output by means of the output unit.

Methods and apparatuses are described for modulating multiple integrated neural networks to alter composite sensory processes, such as audition or hearing. These methods and apparatuses may be used for therapeutic and non-therapeutic uses, including enhancing entertainment and communication, by providing a cranio-cervical tuning apparatus worn in or around the outer ear or auricle. These methods and apparatuses may include functional neurosensory bias for neurosensory scrambling neuromodulation to influence composite or multi-modal sensory processes.

The present invention pertains to a medical treatment device (10) for stimulating neurons of a patient to suppress a pathologically synchronous activity of the neurons. The device (10) comprises a non-invasive stimulation unit (12) configured for simultaneously administering at least one acoustic stimulus and at least one non-acoustic stimulus to a patient's body, each of which is configured to suppress the pathologically synchronous activity when being administered to the patient's body.

Systems and techniques for enhanced sleep tracking, monitoring, and conditioning are discussed herein. A device may be couplable to, or integrally formed with, a piece of furniture (a “nearable”) receives sensor data from one or more sensors accessible to the device and, based on a determined stage of sleep, may actuate one or more devices for conditioning sleep. In some examples, the nearable may be configured to receive a smartphone such that one or more processors and sensors of the smartphone may be used to perform at least some of the processes. When configured to receive a smartphone, the nearable's cavity may retain the smartphone via a spring mechanism to create an additional button for user interaction, as well as be shaped to minimize an amount of electromagnetic radiation (including light emitted from a screen) of the smartphone, while optimizing sounds output from the smartphone.

An anti-drowsiness device includes a head cover; an electroencephalograph, which is formed on the head cover, the electroencephalograph receiving the brain-waves all the time and generating a sleep-detection signal when a specific frequency, which shows drowsiness, is received, and an electrostimulator, which is formed on the head cover, the electrostimulator generating electrostimulation when receiving the sleep-detection signal.

A wearable device and method for multimodal stimulation of the vagus nerve having a pair of ear pieces, which are placed at least partially within the concha of an individual. Each ear piece has at least on electric stimulator which provides electric current to the ear of the individual. The wearable device also has a connection which provides stimulation instructions to the stimulators. The method for multimodal simulation also includes iterative biometric measurement and stimulation.

Techniques (methods and devices) for neural stimulation through audio and/or non-audio stimulation. The techniques may be performed by a processing device and may include receiving an audio signal from an audio source and a desired mental state. An element of the audio signal that correspond to a modulation characteristic of the desired mental state may be identified. An envelope from the element may be determined. One or more non-audio signals may be generated based on at least a rate and phase of the envelope. The one or more non-audio signals may be transmitted to one or more non-audio output devices to generate one or more non-audio outputs. A relative timing of the one or more non-audio outputs and an output of the audio signal may be coordinated. The neural stimulation through audio and/or non-audio stimulation may assist patients before, during, and after anesthesia.