Publications
2022:
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Boucher, PO, Wang, T, Carceroni, L, Kane, G, Shenoy, KV, Chandrasekaran, C (2022). Neural population dynamics in dorsal premotor cortex underlying a reach decision. bioRxiv. [PDF] [DOI]
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Menardi, A, Ozdemir, R A, Momi, D, Tadayon, E, Boucher, P, Vallesi, A, Pascual-Leone, A, Shafi, M M, & Santarnecchi, E (2022). Effect of group-based vs individualized stimulation site selection on reliability of network-targeted TMS. NeuroImage, 264: 119714. [PDF] [DOI]
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Momi, D, Ozdemir, RA, Tadayon, E, Boucher, P, Domenico, AD, Fasolo, M, Shafi, MM, Pascual-Leone, A, and Santarnecchi, E (2022). Phase-dependent local brain states determine the impact of image-guided transcranial magnetic stimulation on motor network electroencephalographic synchronization. The Journal of Physiology, 0:1–17. [PDF] [DOI]
2021:
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Boucher, PO, Ozdemir, RA, Momi, D, Burke, MJ, Jannati, A, Fried, P J, Pascual-Leone, A, Shafi, MM, and Santarnecchi, E (2021). Sham-derived effects and the minimal reliability of theta burst stimulation. Scientific Reports, 11:21170. [PDF] [DOI]
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Momi, D, Ozdemir, RA, Tadayon, E, Boucher, P, Domenico, AD, Fasolo, M, Shafi, MM, Pascual-Leone, A, and Santarnecchi, E (2021). Perturbation of resting-state network nodes preferentially propagates to structurally rather than functionally connected regions. Scientific Reports, 11:12458. [PDF] [DOI]
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Momi, D, Ozdemir, RA, Tadayon, E, Boucher, P, Shafi, MM, Pascual-Leone, A, and Santarnecchi, E (2021). Network-level macroscale structural connectivity predicts propagation of transcranial magnetic stimulation. NeuroImage, 229. [PDF] [DOI]
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Ozdemir, RA, Boucher, P, Fried, PJ, Momi, D, Jannati, A, Pascual-Leone, A, Santarnecchi, E, and Shafi, MM (2021). Reproducibility of cortical response modulation induced by intermittent and continuous theta-burst stimulation of the human motor cortex. Brain Stimulation, 14:949–964. [PDF] [DOI]
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Ozdemir, RA, Tadayon, E, Boucher, P, Sun, H, Momi, D, Ganglberger, W, Westover, MB, Pascual-Leone, A, Santarnecchi, E, and Shafi, MM (2021). Cortical responses to noninvasive perturbations enable individual brain fingerprinting. Brain Stimulation, 14:391–403. [PDF] [DOI]
2020:
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Ozdemir, R, Tadayon, E, Boucher, P, Momi, D, Karakhanyan, K, Fox, M, Halko, M, Pascual-Leone, A, Shafi, M, and Santarnecchi, E (2020). P67 transcranial magnetic stimulation induced perturbations of resting-state-networks are reproducible markers of causal network-to-network dynamics. Clinical Neurophysiology, 131:e50. [PDF] [DOI]
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Ozdemir, R, Tadayon, E, Boucher, P, Sun, H, Ganglberger, W, Westover, B, Pascual-Leone, A, Santarnecchi, E, and Shafi, M (2020). P66 cortical fingerprinting using spatial-temporal evolution of TMS evoked EEG responses. Clinical Neurophysiology, 131:e50. [PDF] [DOI]
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Ozdemir, RA, Tadayon, E, Boucher, P, Momi, D, Karakhanyan, KA, Fox, MD, Halko, MA, Pascual-Leone, A, Shafi, MM, and Santarnecchi, E (2020). Individualized perturbation of the human connectome reveals reproducible biomarkers of network dynamics relevant to cognition. Proceedings of the National Academy of Sciences, 117:8115–8125. [PDF] [DOI]
2019:
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Klooster, D, Vink, J, van Mierlo, P, Boon, P, Cooke, D, Gedankien, T, Roberts, A, Boucher, P, Pascual-Leone, A, Fox, M, and Shafi, M (2019). Propagation of TMS pulses versus functional brain connectivity. Brain Stimulation, 12:450. [PDF] [DOI]
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Ozdemir, R, Tadayon, E, Boucher, P, Momi, D, Karakhanyan, K, Pascual-Leone, A, Shafi, M, and Santarnecchi, E (2019). EEG network-specificity of response to fMRI-guided TMS perturbation of the default mode and dorsal attention networks is correlated with cognition. BrainStimulation, 12:467. [PDF] [DOI]
2016:
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Wammes, JD, Boucher, PO, Seli, P, Cheyne, J A, & Smilek, D (2016). Mind wandering during lectures I: Changes in rates across an entire semester. Scholarship of Teaching and Learning in Psychology, 2(1), 13–32. [PDF] [DOI]
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Wammes, JD, Seli, P, Cheyne, JA, Boucher, PO, and Smilek, D (2016). Mind wandering during lectures II: Relation to academic performance. Scholarship of Teaching and Learning in Psychology, 2:33–48. [PDF] [DOI]
2013: