A transcranial ultrasonic stimulation headset includes a coupling system, one or more ultrasound transducers configured to generate and direct a first focused ultrasound beam at a region within a portion of a subject's brain, one or more sensors configured to measure a response from the portion of the subject's brain in response to the first focused ultrasound beam, and an electronic controller in communication with the one or more ultrasound transducers configured to dynamically adjust, based on the measured response from the portion of the subject's brain, a particular stimulation parameter for the one or more ultrasound transducers to generate and direct a second focused ultrasound beam at the region within a portion of the subject's brain.

First data comprising a first range of audio frequencies is received. The first range of audio frequencies corresponds to a predetermined cochlear region of a listener. Second data comprising a second range of audio frequencies is also received. Third data comprising a first modulated range of audio frequencies is acquired. The third data is acquired by modulating the first range of audio frequencies according to a stimulation protocol that is configured to provide neural stimulation of a brain of the listener. The second data and the third data are arranged to generate an audio composition from the second data and the third data.

A system comprises an ultrasound subsystem and a magnetic resonance imaging (MRI) subsystem. The ultrasound subsystem applies pulses of focused ultrasound having one or more parameters to an identified location in a subject that is to receive treatment. The parameters are determined in accordance with a magnetic resonance guided focused ultrasound (MRgFUS) treatment plan. The MRI subsystem acquires functional image data corresponding to the identified location concurrently with the applied pulses of focused ultrasound. The MRI subsystem obtains a reconstructed series of functional images of the subject using the functional image data. The functional images are indicative of a first region within the identified location in which neuronal activity has been modified by the applied pulses. The system is configured to adjust one or more parameters of the MRgFUS treatment plan using the reconstructed series of functional images.

Systems and methods are disclosed for the treatment and prevention of migraine and other headache conditions, and more specifically to systems and methods of treating and preventing migraine and other headache conditions through noninvasive peripheral nerve stimulation.

In an embodiment, an electrical stimulation system can include one or more of an electrode assembly including one or more electrodes and an electronics subsystem. In some variations, each of the one or more electrodes can include a hydrophilic layer and a conductive layer. In some variations, the electronics subsystem can include one or more of a control module, power module, and a stimulus generator. In some variations, the electrical stimulation can further include one or more of an electrical attachment system, mechanical attachment system, head apparel assembly, flexible housing, and/or any other suitable component. The electrical stimulation system functions to apply electrical stimulation but can additionally or alternatively function to measure/and or record one or more biosignals from a user.

The present specification discloses a neuromodulation system comprising a transcranially mounted neuromodulation device and a stimulation control computing environment. The disclosed neuromodulation device comprising at least one ultrasound transducer and at least one EEG electrode and the disclosed stimulation control computing environment comprises a stimulation control unit and offline computing device, the disclosed stimulation control unit including associated systems and methods for controlling the neuromodulation device functionality using acoustic simulations performed on brain image data as well as methods and uses of such neuromodulation systems in modulating brain activity using focused ultrasound stimulation of the thalamus and thalamic sub regions during certain phases of slow wave brain oscillations in order to treat various neural-based disorders or conditions including sleep disorders.

A method to apply a nerve inhibiting cloud surrounding a blood vessel includes creating a treatment plan, wherein the treatment plan prescribes application of the nerve inhibiting cloud towards at least a majority portion of a circumference of a blood vessel wall, and applying the nerve inhibiting cloud towards the majority portion of the circumference of the blood vessel wall for a time sufficient to inhibit a function of a nerve that surrounds the blood vessel wall.

The present invention is directed to methods for treating neurodegenerative diseases and/or improving cognitive function, in particular those associated with protein oligomers, aggregates or deposits, using acoustic energy, such as ultrasound. An 5 example of such a neurodegenerative disease is Alzheimer's disease. The present invention provides a method of improving cognitive function and/or memory in an individual with impaired memory and/or executive function, the method including the steps of identifying a region of the brain of the individual to be treated with acoustic energy, applying a clinically safe level of acoustic energy to the region, thereby 10 saturating or substantially saturating the region with acoustic energy, thereby improving memory in the individual.

The present invention relates to a brain stimulating device and, particularly, relates to a brain stimulating device comprising: a brainwave measurement unit for outputting a brainwave signal; and a stimulation unit for applying spindle-like stimulation to a brain in accordance with the generation of slow oscillation included in the brainwave signal. The brain stimulating device according to the present invention can reinforce memory or reduce memory deterioration due to dementia. Also, the brain stimulating device according to the present invention can reinforce hippocampus-dependent memory. Further, a portable device according to the present invention can control and monitor the brain stimulating device. Moreover, a method for assessing the performance of the brain stimulating device according to the present invention can assess the performance of the brain stimulating device.

An electronic memory is configured to store pre-recorded neurostimulation data comprising patterns of stimulation of a specified region of a subject's brain developed to recreate a response by one or more of a sensing organ or sensing organs, a vestibular system, and a memory of the subject. A focused ultrasound transducer arrangement is operably coupled to the electronic memory and comprises an array of ultrasound transducers. The focused ultrasound transducer arrangement is configured to deliver transcranial stimulation to the specified region of a person's brain using the pre-recorded neurostimulation data to recreate the response by one or more of the sensing organ or sensing organs, the vestibular system, and the memory of the subject. A support structure is configured for placement on or about a person's head. The support structure is configured to support at least the focused ultrasound transducer arrangement.