Neuromodulation is a fast growing field that offers a wide range of applications for both understanding and treating the brain. Future research for non-invasive neuromodulation will need to elucidate the optimal frequency, duration, and intensity of stimulation for a variety of technologies and diseases. Closed loop stimulation is thus a promising research area that allows for responsive stimulation and real time symptom management. Our project is proposed to develop and test a novel noninvasive neuromodulation integrating transcranial focused ultrasound stimulation (tFUS) with electrophysiological source imaging (ESI-tFUS) to allow evidence-based neuromodulation for brain research and the management of brain conditions. Despite the recent developments and attention surrounding tFUS, relatively little is known about the mechanisms and optimal parameters of this stimulation technology. The addition of ESI neuroimaging, aimed at providing biomarkers to assess the effects of tFUS neuromodulation, could provide crucial necessary information regarding the neural response to the applied stimulation in real-time. In order for tFUS to be further developed and transformed into a robust neuromodulation technology, an integrated electrophysiological source-imaging-guided tFUS system to allow for individualized and responsive stimulation is needed. The purpose of this study is to develop and evaluate the proposed ESI-tFUS in human subjects using motor and somatosensory paradigms.
In this protocol, the following hypothesis will be tested; the electroencephalography (EEG) and transcranial focused ultrasound (tFUS) will be used to quantify and optimize stimulation effects. We will test the hypothesis that tFUS can induce regional brain activity and use EEG to localize and image the brain electrical activity as induced by TFUS stimulation. Subjects will be recruited for MRI scan and then undergo motor and/or sensory tasks, and during these tasks, subjects will receive tFUS and concurrently be monitored by EEG. This tFUS-EEG study is aimed at exploring effects of tFUS and the use of EEG in providing electrophysiological responses to brain activation following tFUS stimulation.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
SINGLE
Enrollment
80
Low-intensity (Ispta \< 720 mW/cm2, Isppa \< 190 W/cm2) transcranial focused ultrasound
Department of Biomedical Engineering, Carnegie Mellon University
Pittsburgh, Pennsylvania, United States
RECRUITINGClosed-loop control of ultrasound neuromodulation as assessed by EEG source imaging
The primary study outcome is a closed-loop control algorithm to control the parameters in administrating the tFUS. The outcome data of the study will include the MRI data, EEG data, tFUS location and timing data, perceptual (subject reported) effects of tFUS and/or pins, and any reported adverse events. Analysis of the EEG data will be conducted using EEG analysis software, and the customized software to be developed at the PI's lab. The EEG data will also be correlated with tFUS application. The output of our data analysis process will be in the form of quantitative spatial estimation of tFUS activation in the brain using EEG source reconstruction.
Time frame: up to 2 years
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