A system and method for therapeutic stimulation using virtual objects and gamification, in which multi-modality stimulus is applied using some combination of virtual elements, attention is enhanced by virtue of the user's active participation, and long-term use is encouraged by virtue of the entertaining nature of the gamification. Depending on configuration, the system and method may comprise a display comprising virtual objects, a light-producing device (other than the display), an audio-producing device such as speakers or headphones, a haptic feedback device such as a vibratory motor, a means for monitoring the user's attention, and a software application which applies therapeutic stimulation using some combination of the display, the light-producing device, the audio-producing device, and the haptic feedback device.

The invention encompasses systems and methods allowing for minimally invasive insertion and functional optimization of implantable electrode arrays designed for placement within the subgaleal space to record brain electrical activity. The implantable arrays comprise a support structure capable of being implanted in the subgaleal space and comprising at least one reference element; at least one ground element; and one or more recording elements; and wherein said array is capable of detecting and/or transmitting a subgaleal electrical signal.

The invention encompasses systems and methods allowing for minimally invasive insertion and functional optimization of implantable electrode arrays designed for placement within the subgaleal space to record brain electrical activity. The implantable arrays comprise a support structure capable of being implanted in the subgaleal space and comprising at least one reference element; at least one ground element; and one or more recording elements; and wherein said array is capable of detecting and/or transmitting a subgaleal electrical signal.

Systems and methods for motor function facilitation are described herein. In one aspect, a computer-implemented method for assisted actuation of a patient movement can include: receiving a set of neural signals from a set of neural sensors; extracting a set of features from the set of neural signals; inputting the set of features into a classification model; determining from the classification model an attempted activity of a user; and transmitting a set of stimulation signals to one or more output effectors according to the attempted activity and the set of neural signals.

An electronic device according to an example embodiment includes a processor, and a memory operatively connected to the processor and including instructions executable by the processor, wherein when the instructions are executed, the processor is configured to collect an EEG signal measuring brain activity and an fNIRS signal measuring the brain activity, and output a result of determining a type of the brain activity from a trained neural network model using the EEG signal and the fNIRS signal, and the neural network model may be trained to, extract an EEG feature from the EEG signal, extract an fNIRS feature from the fNIRS signal, extract a fusion feature based on the EEG signal and the fNIRS signal, and output the result of determining the type of the brain activity based on the EEG feature and the fusion feature.

An electronic device according to an example embodiment includes a processor, and a memory operatively connected to the processor and including instructions executable by the processor, wherein when the instructions are executed, the processor is configured to collect an EEG signal measuring brain activity and an fNIRS signal measuring the brain activity, and output a result of determining a type of the brain activity from a trained neural network model using the EEG signal and the fNIRS signal, and the neural network model may be trained to, extract an EEG feature from the EEG signal, extract an fNIRS feature from the fNIRS signal, extract a fusion feature based on the EEG signal and the fNIRS signal, and output the result of determining the type of the brain activity based on the EEG feature and the fusion feature.

Described are methods, devices, and systems for a novel, inexpensive, easy to use therapy for treatment of anxiety. Described are methods and devices to treat anxiety that involves no medication. Methods and devices described herein use alternating magnetic fields to gently “tune” the brain and affect symptoms of anxiety.

Described are methods, devices, and systems for a novel, inexpensive, easy to use therapy for treatment of anxiety. Described are methods and devices to treat anxiety that involves no medication. Methods and devices described herein use alternating magnetic fields to gently “tune” the brain and affect symptoms of anxiety.

A method is provided which includes receiving first signals indicative of sound in an environment of a recipient. The method further includes receiving second signals indicative of sound perception by the recipient. The method further includes, in response to the first signals and the second signals, determining whether the recipient is experiencing tinnitus. The method further includes, while the recipient is experiencing tinnitus, transmitting stimulation signals to the auditory system of the recipient.

A method is provided which includes receiving first signals indicative of sound in an environment of a recipient. The method further includes receiving second signals indicative of sound perception by the recipient. The method further includes, in response to the first signals and the second signals, determining whether the recipient is experiencing tinnitus. The method further includes, while the recipient is experiencing tinnitus, transmitting stimulation signals to the auditory system of the recipient.