There are a number of disorders of the brain that have limited treatment options, such as chronic pain, addiction, and major depression. A new technology has emerged in the last decade known as transcranial focused ultrasound, which can deliver focused acoustic signals through the skull to modulate brain activity over a small region, including structures deep in the brain. This has resulted in many ongoing clinical trials for various disorders, but there is still a lack of understanding of the optimal sonication parameters for increasing versus decreasing brain activity. The investigators aim to address this open question by sonicating the primary visual cortex and primary auditory cortex in human with a range of sonication parameters. These brain structures were chosen to target because they are expected to elicit perceptual responses in the subject (i.e., the subject will report visual and auditory perception during sonication), allowing the experimenters to infer directly the extent to which neural signals can propagate through the visual and auditory systems in a way that is sufficient to produce conscious perception. Such findings have applications not only in clinical treatments, but also in the fundamental science of the neural basis of sensory perception. Previous work has shown that sonicating the visual cortex in humans can elicit visual perception, but the ultrasonic system in prior work did not have the focusing capabilities that will be employed in this study. At the end of this study, the investigators will have determined the optimal sonication parameters that can elicit neural responses over a small volume over sensory cortex, which can be inferred from visual percepts being localized in space (e.g., a bright spot as opposed to a diffuse light), and auditory percepts that sound like pure tones rather than a broad set of frequencies (e.g., sounding like white noise or static).
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Change in sensory-evoked cortical response measured by electroencephalography
Timeframe: Measured during Visit 2 (baseline, during stimulation, immediately post-stimulation, and 15-20 minutes post-stimulation)
Change in visual detection threshold
Timeframe: Baseline (Visit 1); pre-stimulation (Visit 2); immediately after stimulation (Visit 2); and 1 week after stimulation (Visit 3)
Change in auditory tone detection threshold
Timeframe: Baseline (Visit 1); pre-stimulation (Visit 2); immediately after stimulation (Visit 2); and 1 week after stimulation (Visit 3)