Zachary Haigh scite author profile

Neural oscillations in the primary motor cortex (M1) shape corticospinal excitability. Power and phase of ongoing mu (8-13 Hz) and beta (14-30 Hz) activity may mediate motor cortical output. However, the functional dynamics of both mu and beta phase and power relationships and their interaction, are largely unknown. Here, we employ recently developed real-time targeting of the mu and beta rhythm, to apply phase-specific brain stimulation and probe motor corticospinal excitability non-invasively. For this, we used instantaneous read-out and analysis of ongoing oscillations, targeting four different phases (0, 90, 180, and 270 degrees) of mu and beta rhythms with suprathreshold single-pulse transcranial magnetic stimulation (TMS) to M1. Ensuing motor evoked potentials (MEPs) in the right first dorsal interossei muscle were recorded. Twenty healthy adults took part in this double-blind randomized crossover study. Mixed model regression analyses showed significant phase-dependent modulation of corticospinal output by both mu and beta rhythm. Strikingly, these modulations exhibit a double dissociation. MEPs are larger at the mu trough and rising phase and smaller at the peak and falling phase. For the beta rhythm we found the opposite behavior. Also, mu power, but not beta power, was positively correlated with corticospinal output. Power and phase effects did not interact for either rhythm, suggesting independence between these aspects of oscillations. Our results provide insights into real-time motor cortical oscillation dynamics, which offers the opportunity to improve the effectiveness of TMS by specifically targeting different frequency bands.

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Induced neural phase precession through exogeneous electric fields

Wischnewski

Tran

Zhao

et al. 2023

Preprint

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The gradual shifting of preferred neural spiking relative to local field potentials (LFPs), known as phase precession, plays a prominent role in neural coding. Correlations between the phase precession and behavior have been observed throughout various brain regions. As such, phase precession is suggested to be a global neural mechanism that promotes local neuroplasticity. However, causal evidence and neuroplastic mechanisms of phase precession are lacking so far. Here we show a causal link between LFP dynamics and phase precession. In three experiments, we modulated LFPs in humans, a non-human primate, and computational models using alternating current stimulation. We show that continuous stimulation of motor cortex oscillations in humans lead to a gradual phase shift of maximal corticospinal excitability by ~90 degrees. Further, exogenous alternating current stimulation induced phase precession in a subset of neurons (~17%) in the non-human primate. Multiscale modeling of realistic neural circuits suggests that alternating current stimulation-induced phase precession is driven by NMDA-mediated synaptic plasticity. Altogether, the three experiments provide mechanistic and causal evidence for phase precession as a global neocortical process. Alternating current-induced phase precession and consequently synaptic plasticity is crucial for the development of novel therapeutic neuromodulation methods.

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Modulation of phase-specific motor responses using real-time tACS-TMS in humans

Wischnewski¹,

Tran²,

Zhao³

et al. 2023

Brain Stimulation

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Oscillation Phase-Specific Modulation of Cortical Excitability Using Real-Time TMS-EEG in Stroke

Haigh¹,

Wischnewski²,

Shirinpour³

et al. 2023

Brain Stimulation

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Zachary Haigh

The phase of sensorimotor mu and beta oscillations has the opposite effect on corticospinal excitability

The phase of sensorimotor mu and beta oscillations has the opposite effect on corticospinal excitability

Induced neural phase precession through exogeneous electric fields

Modulation of phase-specific motor responses using real-time tACS-TMS in humans

Oscillation Phase-Specific Modulation of Cortical Excitability Using Real-Time TMS-EEG in Stroke

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