Ivan Alekseichuk

In reverse chronological order,   *equal contribution

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17) Wischnewski M* and Alekseichuk I*, Opitz A (2022). Neurocognitive, physiological, and biophysical effects of transcranial alternating current stimulation. Trends in Cognitive Sciences   {link}

 

16) Alekseichuk I, Wischnewski M, Opitz A (2022). A minimum effective dose for (transcranial) alternating current stimulation. Brain Stimulation   {link}

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15) Wischnewski M, Haigh Z, Shirinpour S, Alekseichuk I, Opitz A (2022). The phase of sensorimotor mu and beta oscillations has the opposite effect on corticospinal excitability. Brain Stimulation   {link}

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14) Wischnewski M, Alekseichuk I, Schutter D (2021). Behavioral and electrocortical effects of transcranial alternating current stimulation during advice-guided decision-making. NeuroImage: Reports    {link}

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13) Johnson L* and Alekseichuk I*, Krieg J, Doyle A, Yu Y, Vitek J, Johnson M, Opitz A (2020). Dose-dependent effects of transcranial alternating current stimulation on spike timing in awake nonhuman primates. Science Advances    {link}

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12) Shirinpour S, Alekseichuk I, Mantell K, Opitz A (2020). Experimental evaluation of methods for real-time eeg phase-specific transcranial magnetic stimulation. Journal of Neural Engineering   {link}

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11) Alekseichuk I* and Turi Z*, Veit S, Paulus W (2020). Neuromodulation of right posterior neocortex promotes encoding of long-term memories. Brain Stimulation   {link}

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10) Alekseichuk I, Falchier AY, Linn G, Xu T, Milham MP, Schroeder CE, Opitz A (2019). Electric field dynamics in the brain during multi-electrode transcranial electric stimulation. Nature Communications    {link}

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9) Alekseichuk I, Mantell K, Shirinpour S, Opitz A (2019). Comparative modeling of transcranial magnetic and electric stimulation in mouse, monkey, and human.  NeuroImage     {link}

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8) Cattaneo Z, Ferrari C, Schiavi S, Alekseichuk I, Antal A, Nadal M (2019). Medial prefrontal cortex involvement in aesthetic appreciation of paintings: a tDCS study. Cognitive Processing    {link}

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7) Turi Z*, Alekseichuk I*, Paulus W (2018). On ways to overcome the magical capacity limit of working memory. PLOS Biology    {link}

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6) Lara GA, Alekseichuk I, Turi Z, Lehr A, Antal A, Paulus W (2018). Perturbation of theta-gamma coupling at the temporal lobe hinders declarative memory. Brain Stimulation     {link}

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5) Alekseichuk I, Pabel SC, Antal A, Paulus W (2017). Intrahemispheric theta rhythm desynchronization impairs working memory. Restorative Neurology and Neuroscience    {link}

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4) Antal A, Alekseichuk I, Bikson M, Brockmöller J, Brunoni AR, Chen R, Cohen LG, Dowthwaite G, Ellrich J, Flöel A, Fregni F, George MS, Hamilton R, Haueisen J, Herrmann CS, Hummel FC, Lefaucheur JP, Liebetanz D, Loo CK, McCaig CD, Miniussi C, Miranda PC, Moliadze V, Nitsche MA, Nowak R, Padberg F, Pascual-Leone A, Poppendieck W, Priori A, Rossi S, Rossini PM, Rothwell J, Rueger MA, Ruffini G, Schellhorn K, Siebner HR, Ugawa Y, Wexler A, Ziemann U, Hallett M, Paulus W (2017). Low intensity transcranial electric stimulation: safety, ethical, legal regulatory and application guidelines. Clinical Neurophysiology    {link}

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3) Alekseichuk I, Turi Z, Lara GA, Antal A, Paulus W (2016). Spatial working memory in humans depends on theta and high gamma synchronization in prefrontal cortex. Current Biology     {link}

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2) Alekseichuk I, Diers K, Paulus W, Antal A (2016). Transcranial electrical stimulation of the occipital cortex during visual perception modifies the magnitude of BOLD activity: a combined TES-FMRI approach. NeuroImage    {link}

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1) Pisoni A, Turi Z, Raithel A, Ambrus GG, Alekseichuk I, Schacht A, Paulus W, Antal A (2015). Separating recognition processes of declarative memory via anodal TDCS: boosting old item recognition by temporal and new item detection by parietal stimulation. PLOS One    {link}