Abstract
Background Owing to its high spatial resolution and penetration depth, transcranial focused ultrasound stimulation (tFUS) is one of the most promising approaches to non-invasive neuromodulation. Identifying the impact of the stimulation waveform and endogenous neural activity on neuromodulation outcome is critical to harnessing the potential of tFUS.
Objective Here we tested a new form of tFUS where the amplitude of the ultrasonic waveform is modulated at a rate much slower than the operating frequency. Moreover, we sought to identify the relationship between pre-stimulation neural activity and the neuronal response to tFUS.
Methods We applied three minutes of amplitude modulated (AM) tFUS at 40 Hz to the rat hippocampus while recording local field potentials (LFP) and multi-unit activity (MUA)from the sonicated region. To assess the role of AM, we also tested continuous-wave (CW) stimulation.
Results AM tFUS reduced firing rate during and immediately after stimulation. On the other hand, CW tFUS produced an acute firing rate increase that was abolished after sonication. For both waveforms, firing rate changes were stronger in units exhibiting high baseline LFP power, particularly in the gamma band (30-250 Hz). The neuromodulatory effect was also influenced by the prevalence of sharp wave ripples (SWR) during the pre-stimulation period, with firing rates modulated by up to 33% at units showing frequent baseline SWR.
Conclusion Our findings suggest that AM and CW tFUS produce qualitatively different neuronal outcomes, and that baseline rhythms may effectively “gate” the response to tFUS.
Competing Interest Statement
The authors have declared no competing interest.