Tiam Hosseinian1, Fatemeh Yavari1, Maria Chiara Biagi2, Min-Fang Kuo1, Giulio Ruffini2, Michael A Nitsche3, Asif Jamil4. 1. Dept. Psychology and Neurosciences, Leibniz Research Centre for Working Environment and Human Factors. Dortmund, Germany. 2. Neuroelectrics, Barcelona, Spain. 3. Dept. Psychology and Neurosciences, Leibniz Research Centre for Working Environment and Human Factors. Dortmund, Germany; Dept. Neurology, University Medical Hospital Bergmannsheil, Bochum, Germany. Electronic address: nitsche@ifado.de. 4. Dept. Psychology and Neurosciences, Leibniz Research Centre for Working Environment and Human Factors. Dortmund, Germany; Laboratory for Neuropsychiatry & Neuromodulation, Harvard Medical School/Massachusetts General Hospital, Boston, MA, USA. Electronic address: ajamil1@mgh.harvard.edu.
Abstract
BACKGROUND: Neural oscillations in the cerebral cortex are associated with a range of cognitive processes and neuropsychiatric disorders. However, non-invasively modulating oscillatory activity remains technically challenging, due to limited strength, duration, or non-synchronization of stimulation waveforms with endogenous rhythms. OBJECTIVE: We hypothesized that applying controllable phase-synchronized repetitive transcranial magnetic stimulation pulses (rTMS) with alternating currents (tACS) may induce and stabilize neuro-oscillatory resting-state activity at targeted frequencies. METHODS: Using a novel circuit to precisely synchronize rTMS pulses with phase of tACS, we empirically tested whether combined, 10-Hz prefrontal bilateral stimulation could induce and stabilize 10-Hz oscillations in the bilateral prefrontal cortex (PFC). 25 healthy participants took part in a repeated-measures design. Whole-brain resting-state EEG in eyes-open (EO) and eyes-closed (EC) was recorded before (baseline), immediately (1-min), and 15- and 30-min after stimulation. Bilateral, phase-synchronized rTMS aligned to the positive tACS peak was compared with rTMS at tACS trough, with bilateral tACS or rTMS on its own, and to sham. RESULTS: 10-Hz resting-state PFC power increased significantly with peak-synchronized rTMS + tACS (EO: 44.64%, EC: 46.30%, p < 0.05) compared to each stimulation protocol on its own, and sham, with effects spanning between prefrontal and parietal regions and sustaining throughout 30-min. No effects were observed with the sham protocol. Moreover, rTMS timed to the negative tACS trough did not induce local or global changes in oscillations. CONCLUSION: Phase-synchronizing rTMS with tACS may be a viable approach for inducing and stabilizing neuro-oscillatory activity, particularly in scenarios where endogenous oscillatory tone is attenuated, such as disorders of consciousness or major depression.
BACKGROUND: Neural oscillations in the cerebral cortex are associated with a range of cognitive processes and neuropsychiatric disorders. However, non-invasively modulating oscillatory activity remains technically challenging, due to limited strength, duration, or non-synchronization of stimulation waveforms with endogenous rhythms. OBJECTIVE: We hypothesized that applying controllable phase-synchronized repetitive transcranial magnetic stimulation pulses (rTMS) with alternating currents (tACS) may induce and stabilize neuro-oscillatory resting-state activity at targeted frequencies. METHODS: Using a novel circuit to precisely synchronize rTMS pulses with phase of tACS, we empirically tested whether combined, 10-Hz prefrontal bilateral stimulation could induce and stabilize 10-Hz oscillations in the bilateral prefrontal cortex (PFC). 25 healthy participants took part in a repeated-measures design. Whole-brain resting-state EEG in eyes-open (EO) and eyes-closed (EC) was recorded before (baseline), immediately (1-min), and 15- and 30-min after stimulation. Bilateral, phase-synchronized rTMS aligned to the positive tACS peak was compared with rTMS at tACS trough, with bilateral tACS or rTMS on its own, and to sham. RESULTS: 10-Hz resting-state PFC power increased significantly with peak-synchronized rTMS + tACS (EO: 44.64%, EC: 46.30%, p < 0.05) compared to each stimulation protocol on its own, and sham, with effects spanning between prefrontal and parietal regions and sustaining throughout 30-min. No effects were observed with the sham protocol. Moreover, rTMS timed to the negative tACS trough did not induce local or global changes in oscillations. CONCLUSION: Phase-synchronizing rTMS with tACS may be a viable approach for inducing and stabilizing neuro-oscillatory activity, particularly in scenarios where endogenous oscillatory tone is attenuated, such as disorders of consciousness or major depression.
Authors: Josef Faller; Jayce Doose; Xiaoxiao Sun; James R Mclntosh; Golbarg T Saber; Yida Lin; Joshua B Teves; Aidan Blankenship; Sarah Huffman; Robin I Goldman; Mark S George; Truman R Brown; Paul Sajda Journal: Brain Stimul Date: 2022-02-26 Impact factor: 8.955