Effects of Transcranial Focused Ultrasound on Human Primary Motor Cortex Using 7T fMRI

Background and Significance:

MRI provides highly detailed spatial maps of cortical and sub-cortical activation. As such, delivering tFUS in the MR scanner can provide critical information on neural activation as a result of tFUS. It is unclear however, if tFUS can generate a detectable blood-oxygen level dependent (BOLD) response. Preliminary evidence in humans (Mueller et al. 2014b; Legon et al. 2015) has demonstrated mostly negative results and highly variable responses perhaps due to the transducer or acoustic intensity levels used, the pulsing strategy employed and/or poor signal to noise ratios. We know from animal work it is possible to detect a change in BOLD response from tFUS if a known signal already exists. Yoo et al. (2011) showed focused ultrasound to attenuate the BOLD signal generated by visual stimuli in visual cortex of rabbits. Thus, it is reasonable to assume that this effect is transferable to humans as the underlying brain physiology producing the BOLD signal is the same.

Here we plan to investigate the effect of tFUS on the BOLD signal in human primary motor (M1). M1 has been chosen for two fundamental reasons. 1) The use of muscle contraction to generate a BOLD signal in M1 allows for investigation tFUS on the peripheral electromyogram (EMG) and 2) spatially specific BOLD responses in the cortex can be generated depending upon the musculature used, thus allowing for precise spatial mapping of effect. The first point is of significant interest because if a detectable effect is demonstrated on peripheral musculature it provides important initial evidence that tFUS operates on cortical motor neurons and descending motor tracts similar to electric and electromagnetic stimulation thus hinting at the cellular populations and mechanisms affected by and responsible for tFUS neuromodulatory effect. The second point confirms with high precision the spatially selective effect of tFUS and if we can establish energy/effect functions from this data, this can also lead to scaling of tFUS energies to elicit specific effects such as inhibition or excitation.

Together, this knowledge will further promote tFUS for cortical stimulation and progress tFUS for subcortical stimulation in humans. This last advancement is the great potential of tFUS. Imagine a small device that can simply be attached to the head for precise stimulation anywhere in the brain in lieu of surgery. This is the ultimate goal of this research, however, before this can be considered, the detailed data from this research proposal is necessary.