A cellular-level in vivo investigative method that provides unprecedented insights into the dynamics of neuronal activities evoked by transcranial magnetic stimulation.

Studying the activity of cortical neurons in rats reveals the subcellular effects of transcranial magnetic stimulation, which is used for the non-invasive treatment of a variety of brain disorders.

Transcranial low-intensity ultrasound applied in block design and at low duty cycles and longer sonication durations can safely and non-invasively suppress human motor-evoked potentials, possibly via GABA-A-mediated inhibitory pathways.

Functional connectivity in the human brain reflects changes in synaptic plasticity induced with repeated paired stimulation.

Disruption of right frontopolar cortex with transcranial magnetic stimulation causes selective deficits in exploratory behavior suggesting that different strategies of exploration are implemented by different neural circuits.

Visual and prefrontal cortex excitability predict individual differences in visual imagery strength, and modulating excitability in these cortical regions causally alters the strength of visual imagery.

Building on previous work (Stagg et al., 2014), it is shown that transcranial direct current stimulation modulates local GABA concentration and functional connectivity in the human motor cortex.

Non-invasive brain stimulation tests and refines a model of lateral prefrontal cortex neural dynamics supporting cognitive control.

Noninvasive stimulation of hippocampal networks increases connectivity in a functionally-specific manner that is highly relevant to effective episodic memory performance that depends on the targeted network.

Changing brain state using feedback from transcranial magnetic stimulation, by training participants to increase or decrease how excitable their motor pathways are.