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2nd International Brain Stimulation Conference | Poster Program

Poster Program

Poster Sessions 1 Monday, 6th March 2017 at 12:30-13:30

[P1.001] Effect of extremely low frecuency magnetic fields on l-dopa-induced dyskinesias and transcription factors in a rat model of Parkinson's disease M. Ramírez-López*, D. Millán-Aldaco, M. Palomero-Rivero, M. Guerra-Crespo, R. Drucker-Colín, Universidad Nacional Autónoma de México, Mexico

[P1.002] Electrical stimulation of the medial prefrontal cortex has anxiolytic like effect on freely moving rats. T. Shimizu*, A. Mitani, Kyoto University, Japan

[P1.003] Optogenetic inhibition of cortex neurons attenuates pain-related affective responses and social behavioral disorder in inflammatory pain rat model R.X. Zhang*

1, F. WU

2, M. Li

2, X. Yuan

1, K. Ren

1, B. Berman

1,

1University of Maryland, USA,

2Shanghai

University of Traditional Chinese Medicine, China

[P1.004] Enhancing low-frequency oscillations using on-demand direct-current stimulation improves motor function after stroke D.S. Ramanathan*

1 ,2, L. Guo

1 ,2, T. Gulati

1 ,2, S.J. Won

1 ,2, G. Davidson

1 ,2, A. Hishinuma

1 ,2, K. Ganguly

1 ,2,

1San

Francisco VA Medical Center, USA, 2

University of California, San Francisco, USA

[P1.005] Deep brain stimulation for the control of the lower urinary tract functions C.W. Peng*, P.Y. Chu, S.C. Chen, Taipei Medical University, Taiwan

[P1.006] A simple simulation model for spiral induced epilepsy A. Rabinovitch*

2, Y. Biton

2, M. Friedmabn

3, I. Aviram

2, D. Braunstein

1,

1Sami Shamoon College of

Engineering, Israel, 2

Ben-Gurion University of the Negev, Israel, 3

Ben-Gurion University, Israel

[P1.007] Distinction of functional corticomuscular coupling in synkinetic and separate movement following stroke X.L. Chen

1, P. Xie*

1, Y.Y. Zhang

1, L.X. Liu

2, Y.H. Du

1,

1Yanshan University, China,

2Qinhuangdao People’s

Hospital, China

[P1.008] Rresearch on corticomuscular coherence based on transfer entropy with parmeters optimization P. Xie*, F.M. Yang, Y.B. Wang, L.L. Wang, C.H. Yang, Yanshan University, China

[P1.009] Resting motor threshold depends on the duration of membrane polarisation L.M. Koponen*

1 ,2, T.P. Mutanen

1 ,2, R.J. Ilmoniemi

1 ,2, J.O. Nieminen

1 ,2,

1Aalto University, Finland,

2Helsinki

University Hospital, Finland

[P1.010] Quantitative evaluation of antiepileptogenic effects of LFS either before or after kindling stimulation using spectral power analysis of extracellular EEG in rats M. Jalilifar, A. Yadollahpour*, A.A. Moazedi, Z. Ghotbeddin, Ahvaz Jundishapur University of Medical Sciences, Iran

[P1.012] Transcranial direct current stimulation facilitates reading training in participants with post-stroke central alexia S.J. Kerry*

1, Z.V.J. Woodhead

1, O.M. Aguilar

1 ,2, Y. Ong Hoon

1, J.S. Hogan

1, K. Pappa

1, A.P. Leff

1, J.

Crinion1,

1University College London, UK,

2Pontificia Universidad Javeriana, Colombia

[P1.013] Mapping original thinking by differential modulation of large-scale cortical networks: functional preservation of creativity in LGG patients T. Gonen*

1, B. Shofty

1, D. Perry

1, R. Levi

1, N. Mayseless

4, A. Korn

1, A. Glikman

1, S. Shamay-Tsoory

3, T.

Hendler1 ,2

, Z. Ram1 ,2

, 1Tel Aviv Medical Center, Israel,

2Tel Aviv University, Israel,

3Haifa University, Israel,

4Stanford University, USA

[P1.014] Post-treatment burden of normality after deep brain stimulation in neurological disorders K. Weber*

1, M. Baertschi

2, M. Radomska

2, J. Flores Alves Dos Santos

1, A. Canuto

2,

1University Hospitals of

Geneva, Switzerland, 2

Nant Foundation, Vaud East Psychiatric Institute, Switzerland

[P1.015] Differences between rTMS and tDCS in the analgesic potential of non-invasive motor cortex stimulation J.P. Lefaucheur

1,

1Clinical Neurophysiology Department, Henri Mondor Hospital, Creteil, France,

2EA4391,

Faculty of Medicine, Creteil, France

[P1.016] Electroconvulsive therapy as a treatment option for intractable epilepsy: a case report A. Ragab*

1, A. Elaghoury

2,

1Cairo University School of Medicine, Egypt,

2Abbassia Mental Hospital, Egypt


[P1.017] Treatment with transcranial pulsed electromagnetic field enhances functional rate-of-force development during chair rise in persons with Parkinson's disease A.S.B. Malling*

1, B.M. Morberg

1, L. Wermuth

1, O. Gredal

2, P. Bech

3, B. Jensen

1,

1University of Southern

Denmark, Denmark, 2

The Danish Rehabilitation Centre for Neuromuscular Diseases, Denmark, 3

University of Copenhagen, Denmark

[P1.019] Neurorehabilitation treatment of dysphagia after-stroke with transcranial direct current stimulation: A clinical case A. Sánchez-Kuhn*

1, Y. Medina

2, M. Pérez-García

3, M. Martínez-Sola

2, P. De Haro

2, P. Flores

1 ,2, F. Sánchez-

Santed1 ,2

, 1University of Almería, Spain,

2Institute of Children Neurorehabilitation InPaula, Spain,

3Clínica

Tecnológica Médica, Spain

[P1.021] Deep TMS augmentation treatment for fibromyalgia: A safety and feasibility study B. Cohen

5, J.N. Ablin

1, Y. Braw

3, Y. Bloch

1 ,4, H. Maoz

1 ,4, Y. Levkovitz

1 ,5, K. Lapidus

2, U. Nitzan*

1 ,4,

1Tel-Aviv

University, Israel, 2

Zucker Hillside Hospital, USA, 3

Ariel University, Israel, 4

Shalvata Mental Health Center, Israel,

5Beer Yakov & Nes Ziona mental health center, Israel

[P1.022] Modulation of hippocampal neurogenesis in awake rats by electrical and chemical thalamic stimulation F. Chamaa

1, K. Makkawi

1, W. Sweidan

1 ,2, Z. Nahas*

1, N. Saade

1, W. Abou-Kheir

1,

1American University of

Beirut, Lebanon, 2

Wayne State University, USA

[P1.023] The effects of transcranial pulsed electromagnetic fields in the treatment of Parkinson’s disease B.M. Morberg*

1, A.S. Malling

1, B.R. Jensen

1, O. Gredal

2, P. Bech

3, L. Wermuth

1,

1University of Southern

Denmark, Denmark, 2

The Danish Rehabilitation Centre for Neuromuscular Diseases, Denmark, 3

University of Copenhagen, Denmark

[P1.024] Epidural cortical stimulation for the treatment of chronic resistant tinnitus A. Balossier*, R. Carron, J. Régis, La Timone hospital, France

[P1.025] Cytokine Response to Dual-Target rTMS Treatment Protocol in Parkinson's Disease G. Idova

1 ,2, M. Gevorgyan

1, S. Zhanaeva

1, E. Alperina

1, K. Kulikova

1, S. Dzemidovich

1, K. Danilenko

1, L.

Aftanas*1 ,2

, 1Scientific Research Institute of Physiology & Basic Medicine, Russia,

2Novosibirsk State

University, Russia

[P1.026] An improved protocol for single pulse electrical stimulation for identifying epileptogenic tissue in epilepsy surgery patients D. van Blooijs*

1, G.J. Hebbink

1 ,2, F.S.S. Leijten

1, H.G.E. Meijer

2, S.A. van Gils

2, G.J.M. Huiskamp

1,

1University

Medical Center Utrecht, The Netherlands, 2

University of Twente, The Netherlands

[P1.027] Repetitive TMS of the default mode network: a randomized, double-blinded, cross-over study trial in MCI patients. F. Di Lorenzo*

1 ,4, S. Bonnì

1, S. Picazio

1,

1IRCCS Fondazione Santa LUcia, Italy,

2Neuroimaging Laboratory,

Santa Lucia Foundation, Italy, 3

Stroke Unit, Policlinico Tor Vergata, Italy, 4

Memory Clinic, Policlinico Tor Vergata, Italy

[P1.028] Promoting motor recovery in patients with stroke enhancing cerebellar cortical plasticity: a randomized double blinded controlled repetitive TMS trial F. Di Lorenzo*

1 ,2, S. Bonnì

1, E.P. Casula

1,

1Non Invasive Brain Stimulation Unit, IRCCS Fondazione Santa

Lucia, Italy, 2

Tor Vergata University, Italy, 3

Stroke Unit, Policlinico Tor Vergata, Italy, 4

Neuroimaging Laboratory, Santa Lucia Foundation, Italy

[P1.029] Non-invasive brain stimulation in children with autism spectrum disorder L. Gómez*

1, B. Vidal

2 ,1, M. Denis

1, T. Marín

1, C. Maragoto

1, H. Vera

1, M. Serguera

2, L. Morales

1, M. Báez

1, A.

Sánchez1,

1International Center for Neurological Restoration, Cuba,

2Borrás-Marfán Hospital, Cuba

[P1.030] Clinically-relevant outcomes of deep transcranial magnetic stimulation (dtms) in unipolar major depression: a systematic review and meta-analysis K.K. Kedzior*

1, C. Müller

1, I. Gerkensmeier

1, H.M. Gellersen

2, M. Schuchinsky

3,

1University of Bremen,

Germany, 2

Maastricht University, The Netherlands, 3

University of Limerick, Ireland

[P1.031] How deep is the deep transcranial magnetic stimulation (dtms)? Putative stimulation of reward pathways in substance use disorders: a systematic review and meta-analysis K.K. Kedzior*

1, I. Gerkensmeier

1, M. Schuchinsky

2,

1University of Bremen, Germany,

2University of Limerick,

Ireland

[P1.032] Sleep disturbances in obsessive-compulsive disorder: association with non-response to repetitive transcranial magnetic stimulation (rTMS) L. Donse*

1 ,4, A.T. Sack

4 ,5, P.B. Fitzgerald

6, M. Arns

1 ,2,

1Research Institute Brainclinics, The Netherlands,

2Utrecht University, The Netherlands,

3neuroCare Group, Germany,

4Maastricht University, The Netherlands,


5Maastricht Brain Imaging Center, The Netherlands,

6The Alfred and Monash University, Australia

[P1.033] Assessing and Stabilizing aberrant neuroplasticity in Autism Spectrum Disorder using Transcranial Magnetic Stimulation: Preliminary findings from a proof-of-principle study P. Desarkar*

1 ,3, T.K. Rajji

1 ,3, S.H. Ameis

1 ,2, M.C. Lai

1 ,2, D. Blumberger

1 ,3, Z.J. Daskalakis

1 ,3,

1University of

Toronto, Canada, 2

The Hospital for Sick Children, Canada, 3

Temerty Centre for Therapeutic Brain Intervention, Canada

[P1.034] Efficacy of high-frequency neuronavigated rTMS in auditory verbal hallucinations: a double-blind controlled study in patients with schizophrenia O. Etard*

1 ,3, C. Nathou

1 ,3, R. Morello

2, S. Dollfus

1 ,3,

1Unicaen, France,

2CHU de Caen, France,

3CNRS UMR

6301, France

[P1.035] The efficacy of twice-daily versus once-daily sessions of repetitive transcranial magnetic stimulation in the treatment of major depressive disorder M.M. Modirrousta*, B.M. Meek, S.W. Wikstrom, University of Manitoba, Canada

[P1.036] Comparing depression severity after high-frequency repetitive transcranial magnetic stimulation (rtms) with h1-coil vs. figure-of-eight (f8)-coil in unipolar major depression: a systematic review and meta-analysis K.K. Kedzior*

1, C. Müller

1, H.M. Gellersen

2,


2Maastricht University, The

Netherlands

[P1.037] Repetition suppression in transcranial magnetic stimulation induced motor evoked potentials is impaired in schizophrenic patients E. Kallioniemi*

1, S. Määttä

1, M. Könönen

1, P. Julkunen

1 ,2, L. Säisänen

1 ,2, E. Mervaala

1 ,2, O. Kaarre

1 ,2, E.

Laukkanen1 ,2

, J. Tiihonen4 ,5

, H. Tuppurainen1 ,3

, 1Kuopio University Hospital, Finland,

2University of Eastern

Finland, Finland, 3

Niuvanniemi Hospital, Finland, 4

National Institute for Health and Welfare, Finland,

5Karolinska Institutet, Sweden

[P1.038] Abnormal response to a high frequency TMS partly restores to a healthy level after rTMS treatment in Schizophrenic patients E. Kallioniemi*

1, S. Määttä

1, M. Könönen

1, P. Julkunen

1 ,2, E. Mervaala

1 ,2, O. Kaarre

1 ,2, E. Laukkanen

1 ,2, J.

Tiihonen4 ,5

, H. Tuppurainen3,

1Kuopio University Hospital, Finland,

2University of Eastern Finland, Finland,

3Niuvanniemi Hospital, Finland,

4National Institute for Health and Welfare, Finland,

5Karolinska Institutet,

Finland

[P1.039] Design of the theta burst versus high frequency rTMS effectiveness evaluation in depression (THREE-D) non-inferiority trial D.M. Blumberger*

1, F. Vila-Rodriguez

2, Z.J. Daskalakis

1, P. Giacobbe

1, R.W. Lam

2, S.H. Kennedy

1, J.

Downar1,

1University of Toronto, Canada,

2University of British Columbia, Canada

[P1.040] Stimulating young minds: Investigating a next generation treatment for depression in youth M. Kaur*

1 ,2, D.F. Hermens

2, R.S.C. Lee

2, J. Lagopoulos

2 ,3, S.L. Naismith


1, E.M. Scott

2 ,5, I.B.

Hickie2,

1Monash Alfred Psychiatry research centre, Australia,

2University of Sydney, Australia,

3University of

the Sunshine Coast, Australia, 4

University of Sydney, Australia, 5

Young Adult Mental Health Service, Australia

[P1.041] Posttraumatic growth factor in baseline state predicts transcranial direct current stimulation treatment effects in patients with post-traumatic stress patients: An interim analysis H. Jeon*

1, K-I. Jang

1 ,2, S-H. Lee

1 ,3,

1Clinical Emotion and Cognition Research Laboratory, Republic of Korea,

2The Catholic University of Korea College of Medicine, Republic of Korea,

3Inje University College of Medicine,

Republic of Korea

[P1.042] Abnormal cortical asymmetry as a target for neuromodulation in neuropsychiatric disorders: A conceptual proposal R.W. Beck*

1, J. Laugharne

2, R. Laugharne

3, W. Woldman

3, B. McLean

4, C. Mastropasqua

1, R. Jorge

1, R.

Shankar3,

1Institute of Functional Neuroscience, Australia,

2University of Western Australia, Australia,

3University of Exeter, UK,

4Royal Cornwall Hospital, UK

[P1.043] The emerging therapeutic role of the non-invasive brain stimulation in the addiction medicine: review of the ongoing studies A. Elaghoury, Abbassia Mental Hospital, Egypt

[P1.044] Altered cortical inhibition in schizophrenia: Trait or state marker? M. Ruiz-Veguilla

1, J.F. Martin-Rodriguez*

2, F.J. Palomar

2, P. Porcacchia

2, P.A. de Toledo

2, S. Perona-

Garcelan1, J.F. Rodriguez-Testal

1 ,3, P. Mir

2 ,4,

1UGC Salud Mental HVR, Spain,

2Universidad de Sevilla, Spain,

3Centro de Investigación Biomédica en Red sobre Enfermedades Neurodegenerativas (CIBERNED), Spain


[P1.045] Can cognitive measures predict clinical response to the treatment of major depression with repetitive transcranial magnetic stimulation? M.M. Modirrousta*, B.M. Meek, P.M. Mansouri, University of Manitoba, Canada

[P1.046] Clinical predictors of antidepressant response of repetitive transcranial magnetic stimulation in depressive disorder: A naturalistic study R. Rostami*

1 ,2, R. Kazemi

2,

1Tehran University, Iran,

2Atieh Clinical Neuroscience Center, Iran

[P1.047] TMS investigation of cortical inhibition and facilitation in autism spectrum disorder T.A. Jarczok*

1, C. Luckhardt

1, C.M. Freitag

1, H. Althen

1, S. Bender

1,

1Department of Child and Adolescent

Psychiatry, University Hospital Frankfurt a. Main, Germany, 2

Department of Child and Adolescent Psychiatry, University Hospital Köln, Germany

[P1.048] Repetitive transcranial magnetic stimulation (rTMS) can be safely and feasibly applied to the dorsolateral prefrontal cortex (DLPFC) of non-treatment seeking heavy cannabis users G.L. Sahlem*, B.W. Badran, N.L. Baker, A. Franz, M.S. George, R.J. Malcolm, A.L. McRae-Clark, Medical University of South Carolina, USA

[P1.049] Cortical inhibitory markers of suicidality in depressed adolescents C.P. Lewis*

1, J. Kohli

1, C.J. Blacker

1, D. Doruk

1, J.L. Vande Voort

1, M.A. Frye

1, Z.J. Daskalakis

2, P.E.

Croarkin1,

1Mayo Clinic, USA,

2Centre for Addiction and Mental Health, Canada

[P1.050] Duration of antidepressant response to repetitive transcranial magnetic stimulation: a meta-analysis S. Senova

1 ,4, G. Cotovio

1 ,3, A.J. Oliveira-Maia*

1 ,2,

1Champalimaud Centre for the Unknown, Portugal,

2NOVA

School of Medicine, Portugal, 3

Centro Hospitalar de Lisboa Ocidental, Portugal, 4

CHU Henri Mondor, France

[P1.051] Efficacy of rTMS to treat insomnia in patients without depression A. Tello*, M. Gerez, Hospital Espanol, Mexico

[P1.052] New EEG measures at the beginning of MDD rTMS treatment predict its efficiency: preliminary results R. Shani-Hershkovich*

1, D. Haor

1 ,2, A. Amit

1, U. Alyagon

2, D. Shmuel

4, A. Zangen

2, Y. Levkovitz

3 ,4, A.B. Geva

1

,2, Z. Peremen

1 ,3,

1ElMindA LTD., Israel,

2Ben Gurion University, Israel,

3Tel Aviv University, Israel,

4Beer-

Yaacov Mental Health Center, Israel

[P1.053] HD-tDCS for combat related PTSD: A case series B.M. Hampstead*

1 ,2, S. Garcia

1, S. Schlaefflin

2, K.E. Porter

1 ,2, E.R. Smith

1 ,2, B. Martis

1 ,2, S. Peltier

2,

1VA Ann

Arbor Healthcare System, USA, 2

University of Michigan, USA

[P1.054] One session of Repetitive Transcranial Magnetic Stimulation (rTMS) can improve catatonia features associated with Major Depressive Disorder (MDD): Case study A. Marei*, H. Rashed, Brains' Clinic Maadi, Egypt

[P1.055] Repetitive transcranial magnetic stimulation (rTMS) side effect characterization for treatment resistant depression: Non-inferiority rTMS trial A. Humaira*

1, J. Downar

2, D. Blumberger

2, K. Green

1, E. McLellan

1, N. Ainsworth

1, M. Danilewitz

1, C. Dobek

1,

C. Pang1, J. Brown

1,

1University of British Columbia, Canada,

2University of Toronto, Canada

[P1.056] Computer-assisted cognitive behavior therapy to prevent relapse following electroconvulsive therapy R. Ostroff*, S. Wilkinson, G. Sanacora, Yale University, USA

[P1.057] Cathodal/Anodal technique use of repetitive transcrainal magnetic stimulation in treatment of Autism Spectrum Disorder (ASD) A. Marei*, H. Rashed, R. Magdy, Brains' Clinic Maadi, Egypt

[P1.058] Non-invasive brain stimulation – a modern approach to improved therapy of anxiety disorders? A.J. Fallgatter, University of Tuebingen, Germany

[P1.059] Procedural psychiatry – a new kind of psychiatry that uses machines R. Berlow, ABSC, USA

[P1.060] Modulation of long-term memory using auditory beat stimulation L. Chaieb*

1, M. Höhne

1, B. Staresina

1 ,2, C.E. Elger

1, K. Hampel

1, R. Surges

1, J. Fell

1,

1University of Bonn,

Germany, 2

University of Birmingham, UK

[P1.061] Behavioural and neurophysiological effects of transcranial electrical stimulation (tES) in healthy and depressed individuals: A TMS-EEG study O.W. Murphy*, K.E. Hoy, P.B. Fitzgerald, D. Wong, R.A. Segrave, Monash University, Australia

[P1.062] High definition transcranial direct current stimulation over the dorsomedial prefrontal cortex increases the salience of others A.K. Martin*, I. Dzafic, S. Ramdave, M. Meinzer, University of Queensland, Australia


[P1.063] A combined TMS-EEG investigation of autism spectrum disorder M. Kirkovski*

1 ,2, N.C. Rogasch

2, T. Saeki

3, B.M. Fitzgibbon

1, P.G. Enticott


2,

1Deakin

University, Australia, 2

Monash University, Australia, 3

Yokohama City University, Japan

[P1.064] Recognition-induced forgetting and retrieval-induced forgetting are differentially affected by direct-current stimulation A.M. Maxcey*

1, H. Glenn

2, G.F. Woodman

2,

1The Ohio State University, USA,

2Vanderbilt University, USA

[P1.065] Time-course of mirror neuron activity with repeated emotion embedded action observation V.I. Bagewadi*, U.M. Mehta, J. Thirthalli, National Institute Of Mental Health And Neurosciences, India

[P1.066] Brain stimulation, aging and cognition M.R.L. Emonson*


1 ,2, N.C. Rogasch

2, K.E. Hoy

1 ,2,

1The Alfred and Monash University,

Australia, 2

Monash University, Australia

[P1.067] Electrical brain stimulation at rewarding areas for improving extinction and mossy fiber synaptogenesis G. Huguet*

1, C. Tapias-Espinosa

2, L. Aldavert-Vera

2, E. Kádár

1, P. Segura-Torres

1,

1Universitat de Girona,

Spain, 2

Universitat Autònoma de Barcelona, Spain

[P1.068] Effect of hf-tRNS on attention and neural coherence E. Kvasnak*, M.C. Andersen, Charles University, Czech Republic

[P1.070] Polarity-specific modulations of mental representations by prefrontal tDCS depend on task set P.A. Schroeder*, H-C. Nuerk, C. Plewnia, University of Tübingen, Germany

[P1.071] Cognition and electrical stimulation of cranial nerves D. Adair*

1, M. Bikson

2, D.Q. Truong

2, L. Ho

2, H. Borges

1 ,2,

1City University of New York, USA,

2City College of

New York, USA, 3

Columbia University, USA

[P1.072] Enhancement of processing speed and frustration tolerance with anodal tDCS C. Plewnia, University of Tübingen, Germany

[P1.073] Relationships across, alpha/beta EEG power, learning and memory, and TMS-based neurophysiology measures in persons with Alzheimer’s disease, Type-2 diabetes, and controls C. Benwell*

1, P. Davila-Perez

2, P.J. Fried

2, M. Shafi

2, A. Pascual-Leone

2,

1University of Glasgow, UK,

2Harvard

Medical School, USA

[P1.074] Continuous theta-burst stimulation of medial prefrontal cortex enhances schema-linked encoding A.N. Vorobiova*

1, A.A. Shpektor

1 ,2, M. Feurra

1,

1National Research University Higher School of Economics,

Russia, 2

University of Oxford, UK

[P1.075] Repetitive Transcranial Magnetic Stimulation (rTMS) and Occupational Therapy (OT) can improve cognitive deficits due to anti N-methyl-D-aspartate receptor (NMDA) Encephalitis in 4 weeks: Case study A. Marei*, H. Rashed, F. Sabra, Brains' Clinic Maadi, Egypt

[P1.076] The effects of tSMS on conscious perception of sensory inputs from the hand A. Oliviero*

1, L. Rattagan

2, M. Campolo

2, J. Casanova-Molla

2, J. Valls-Sole

2,

1Hospital Nacional de

Parapléjicos, Spain, 2

Hospital Clinic, Spain

[P1.077] Structural plasticity induced by motor learning – implication to optimize bran stimulation C. Hosoda*

1, T. Nariai

2, Y. Nonaka

1, K. Okanoya

1,

1University of Tokyo, Japan,

2Tokyo Medical and dental

University, Japan

[P1.078] BDNF Val66Met polymorphism modulates brain activity responses following rTMS-induced memory dysfunction. P. Martin-Trias*

1, L. Lanteaume

2, E. Solana

3, C. Cassé-Perrot

2, S. Fernández-Cabello

1, C. Babiloni

4 ,5, C. del

Percio6, C. Junqué

1, P.M. Rossini

5 ,7, J. Micallef

2,

1University of Barcelona, Spain,

2Aix-Marseille University,

France, 3

Institut d'Investigacions Biomèdiques August Pi i Sunyer (IDIBAPS), Spain, 4

University of Rome, Italy,

5IRCCS San Raffaele Pisana, Italy,

6IRCCS SDN, Italy,

7Catholic University, Italy,

8Timone University Hospital,

France, 9

University of Lille, France, 10

Hospital Clinic, Spain, 11

University of Siena, Italy, 12

Harvard Medical School, USA,

13GlaxoSmithKline R&D, UK

[P1.079] The role of parietal cortex during monitoring of involuntary movement: a combined TMS and tDCS study F. Garbarini*

1, V. Bruno

1, C. Fossataro

1, L. Zigiotto

2 ,3, N. Bolognini

2 ,3,

1Dipartimento di Psicologia, Università

di Torino, Italy, 2

Department of Psychology, University of Milano Bicocca, Italy, 3

University of Turin, Italy

[P1.080] The role of premotor cortex in action monitoring: a transcranial magnetic stimulation study A. Salatino*, A. Piedimonte, P. Sarasso, F. Garbarini, R. Ricci, A. Berti, University of Turin, Italy

[P1.081] Associations between clinical outcome and navigated TMS characteristics in patients with motor-eloquent brain lesions: a combined nTMS –fiber tracking approach N. Sollmann*, N. Wildschutz, T. Boeckh-Behrens, B. Meyer, S.M. Krieg, Technische Universität München,


Germany

[P1.082] Prefrontal-limbic connectivity predicts antidepressant efficacy of individual rTMS sites A. Weigand*

1 ,2, A. Horn

1, R. Caballero

1 ,3, A.P. Stern

1, E.H. Wilker

4, D. Press

1, A. Pascual-Leone

1, M.D. Fox

1

,4,

1Harvard Medical School and Beth Israel Deaconess Medical Center, USA,

2Humboldt University of Berlin,

Germany, 3

Universidad Politécnica de Madrid, Spain, 4

Massachusetts General Hospital, USA

[P1.083] Neural correlates of corticospinal excitability of the dominant hand C. Rosso*

1 ,2, V. Perlbarg

2, R. Valabregue

2, E. Moulton

2, S. Meunier

1 ,2, J.C. Lamy

2,

1Hôpital Pitié-Salpêtrière,

France, 2

Institut du cerveau et de la moelle, France

[P1.084] Social cognition and the temporoparietal junction: A double-blind HD-tDCS EEG study P.H. Donaldson*, M. Kirkovski, N.J. Rinehart, P.G. Enticott, Deakin University, Australia

[P1.085] TDCS polarity-dependent neuroplasticity changes in physiological brain aging: a multimodal study M.C. Pellicciari*

1, C. Rodella

1 ,2, J. Cespon

1, P.M. Rossini

2, C. Miniussi

1 ,3,

1IRCCS Centro San Giovanni di Dio

Fatebenefratelli, Italy, 2

Catholic University of Sacred Heart, Italy, 3

CIMeC University of Trento, Italy

[P1.086] Concurrent diffuse optical measurement of cerebral hemodynamics and EEG during transcranial direct current stimulation (tDCS) in humans M. Giovannella

1, G. Mitjà

2, C. Gregori-Pla

1, M. Kacprzak

1, D. Ibañez*

3, G. Ruffini

2 ,3, T. Durduran

1 ,4,

1ICFO -

The Institute of Photonic Science, Spain, 2

Neuroelectrics, Spain, 3

Starlab, Spain, 4

Institució Catalana de Recerca i Estudis Avançats (ICREA), Spain

[P1.087] Test-retest reliability of transcranial direct current stimulation-induced modulation of resting-state sensorimotor cortex oxygenation time course P. Besson*

1, G. Vergotte

1, M. Muthalib

1 ,2, S. Perrey

1,

1University of Montpellier, France,

2Deakin University,

Australia

[P1.088] Acute neural imaging reaction of rTMS to Esophageal cancer patients with depression Q.W. Mu*, Z.W. Guo, J.Q. Yang, H.P. Chen, The Second Clinical Medical College of North Sichuan Medical College Nanchong Central Hospital, China

[P1.090] Modulation of interhemispheric functional connectivity by paired associative stimulation in the prefrontal cortex S. Zibman*, U. Alyagon, A. Zangen, Ben Gurion University of the Negev, Israel

[P1.091] Differential outcomes of rTMS and anesthesia effects on functional connectivity in the rat brain J. Boonzaier*

1, G.A.F. van Tilborg

1, M. Straathof

1, P.I. Petrov

1, C.L. van Heijningen

1, G. van Vliet

1, N. Smirnov

2,

A. van der Toorn1, S.F. Neggers

1, R.M. Dijkhuizen

1,

1University Medical Center Utrecht, The Netherlands,

2Neurosoft, Russia

[P1.092] The effect of high definition tDCS on cognitive control: A behavioral and fMRI study O. Gbadeyan*

1, M. Steinhauser

2, A. Martin

1, K. McMahon

1, L. Ulm

1, M. Meinzer

1,

1The University of

Queensland, Australia, 2

Catholic University of Eichstätt-Ingolstadt, Germany

[P1.093] Interaction between physical fitness and brain network plasticity induced by rTMS J. Hendrikse*, N. Rogasch, J. Coxon, C. Suo, R. Da Costa, M. Yucel, Monash University, Australia

[P1.094] Transcranial Direct Current Stimulation and neural reorganisation after aphasia treatment R.M.A. Blom-Smink*

1 ,2, K. Spielmann

1 ,2, C.P.M. Orellana

2 ,3, M. Smits

2, J. Crinion

4, W.M.E. van de Sandt-

Koenderman1 ,2

, G.M. Ribbers1 ,2

, 1Rijndam Rehabilitation, The Netherlands,

2University Medical Centre, The

Netherlands, 3

Pontifical Catholic University of Chile, Chile, 4

University College London, UK

[P1.095] Modulation of physiologic artifacts during concurrent tDCS and EEG N. Gebodh*

1, D. Adair

2, K. Chelette

3, Z. Esmaeilpour

1 ,4, M. Bikson

1, J. Dmochowski

1, L.C. Parra

1, A.J. Woods

5,

E. Kappenman6,

1The City College of New York, USA,

2The Graduate Center at City University of New York,

USA, 3

ANT Neuro North America, USA, 4

Amirkabir University of Technology, Iran, 5

University of Florida, USA,

6University of California, USA

[P1.096] Imaging of ultrasound stimulation on zebrafish neural development with light-sheet microscopy Z. Qiu*, F. Cao, Y. Yang, L. Sun, The Hong Kong Polytechnic University, Hong Kong

[P1.097] Differential functional connectivity responses to iTBS in young and elder subjects. Association with memory performance. K. Abellaneda-Pérez*

1 ,2, L. Vaqué-Alcázar

1 ,2, P. Martín-Trias

1 ,2, E. Solana

2, D. Vidal-Piñeiro

3, H. Baggio

1 ,2, N.

Bargalló2 ,4

, J. Valls-Solé4, A. Pascual-Leone

5 ,6, D. Bartrés-Faz

1 ,2,

1University of Barcelona, Spain,

2Institute of

Biomedical Research August Pi i Sunyer (IDIBAPS), Spain, 3

University of Oslo, Norway, 4

Hospital Clínic de Barcelona, Spain,

5Harvard University, USA,

6Autonomous University of Barcelona, Spain


[P1.098] Transcranial direct and alternating currentstimulation exert differential expression of brain networks during a workingmemory task L. Vaqué-Alcázar

1 ,2, K. Abellaneda-Pérez*

1 ,2, R. Sala-Llonch

1, N. Bargalló

3, A. Pascual-Leone

4 ,5, D. Bartrés-

Faz1 ,2

, 1University of Barcelona, Spain,

2Institute of Biomedical Research August Pi i Sunyer (IDIBAPS), Spain,

3Hospital Clínic de Barcelona, Spain,

4Harvard University, USA,

5Autonomous University of Barcelona, Spain

[P1.099] Combined TMS-EEG to explore resting state brain dynamics and its transients M. Bonnard*

1 ,3, S. Chen

1 ,2, M. Carrere

1, M. Woodman

1, V. Jirsa

1 ,3,

1Aix-Marseille University, France,

2Inserm, France,

3CNRS, France

[P1.100] Response to 10 Hz rTMS or iTBS to the left DLPFC is associated with increased cortico-striatal connectivity. S.K. Peters

1 ,2, K. Dunlop

1 ,2, F. Mansouri

1, P. Giacobbe


1, R.W. Lam

3, S.H. Kennedy

1, F. Vila-

Rodriguez3, D.M. Blumberger

1, J. Downar*

1 ,2,


2Toronto Western Hospital,

Canada, 3

University of British Columbia, Canada

[P1.101] Effects of continuous theta burst stimulation over the DLPFC on language production in late bilinguals L.B. Jost*

1, M.I. Pestalozzi

1, D. Cazzoli

2, M.R. Müri

2 ,3, M. Mouthon

1, L. Spierer

1, J-M. Annoni

1,

1University of

Fribourg, Switzerland, 2

University of Bern, Switzerland, 3

Bern University Hospital, Switzerland

[P1.102] Stimulation of the somatosensory cortex using HD-tDCS modulates others' pain perception; Combined evidence from behaviour, EEG, fMRI data S. Gallo*

1, T. Maskaljunas

1, B. Lammes

1, C. Henriques

1, J. Suttrup

1, C. Keysers

1 ,2, V. Gazzola

1 ,2,

1Netherlands

Institute for Neuroscience, The Netherlands, 2

University of Amsterdam, The Netherlands

[P1.104] Towards closed-loop transcranial electrical stimulation: a comparison of methods for real time tES-EEG artefact removal using a phantom head model S. Kohli*

1, S. Krachunov

2, A.J. Casson

1,

1University of Manchester, UK,

2University of Cambridge, UK

[P1.105] The efficacy of repetitive transcranial magnetic stimulation of left DLPFC with personalized targeting in major depression: preliminary results of pseudo-randomised study A. Poydasheva*

1, E. Zmeykina

1, A. Chernyavskiy

2, A. Chervyakov

1, J. Lykova

3, N. Suponeva

1, M.

Piradov1,

1Recearch Center of Neurology, Russia,

2Russian Academy of Sciences, Russia,

3I. M. Sechenov First

Moscow State Medical Univercity, Russia

[P1.106] Transcranial magnetic stimulation of the dorsolateral prefrontal cortex during rest and working memory activation H. Althen*

1, H. Moessinger

1, C. Luckhardt

1, C.M. Freitag

1, S. Bender

1 ,2, T.A. Jarczok

1,

1University Hospital

Goethe University Frankfurt, Germany, 2

University Hospital Cologne, Germany

[P1.107] MRI-compatible bilateral tDCS in rats: effects on functional connectivity in the sensorimotor network D.J. Ardesch, J. Boonzaier*, C.L. van Heiningen, G. van Vliet, S.F. Neggers, A. van der Toorn, R.M. Dijkhuizen, University Medical Center Utrecht, The Netherlands

[P1.108] The influence of theta burst stimulation on cognitive functions as assessed by fMRI Stroop task L. Anderkova*, M. Gajdos, E. Koritakova, I. Rektorova, Masaryk University, Czech Republic

[P1.109] Brain stimulation and recording with ultra-flexible PEDOT-CNT-coated micro-ECoG electrode arrays L. Pazzini*

1, D. Polese

1, L. Maiolo

1, E. Castagnola

2, E. Maggiolini

2, E. Zucchini

2, M. Marrani

1, G. Fortunato

1, L.

Fadiga2 ,3

, D. Ricci2,

1IMM-CNR, Italy,

2CTNS@UniFe, Istituto Italiano di Tecnologia, Italy,

3University of

Ferrara, Italy

[P1.110] Low-frequency transcranial magnetic stimulation of the mesio-frontal cortex modulates its connectivity with basal ganglia T. Popa*

1, L.S. Morris

2 ,3, R. Hunt

1, Z.D. Deng

4 ,5, H. Shitara

1, K. Baek

2, M. Hallett

1, V. Voon

2,

1National

Institute of Neurological Disorders and Stroke, USA, 2

University of Cambridge, UK, 3

Oakland University William Beaumont School of Medicine, USA,

4National Institute of Mental Health, USA,

5Duke University

School of Medicine, USA

[P1.111] Removal of high-voltage brain stimulation artifacts from simultaneous EEG recordings S. Lee*

1 ,2, Z.J. Wang

2, M.J. McKeown

1 ,2,

1Pacific Parkinson's Research Centre, Canada,

2University of British

Columbia, Canada

[P1.112] Cortico-cortical potentials mapping of the face recognition network C. Kapeller

1, K. Kamada

2, H. Ogawa

2, R. Prueckl

1, B. Otal*

3, C. Guger

1 ,3,

1Guger Technologies OG, Austria,

2Asahikawa Medical University, Japan,

3g.tec medical engineering Spain, Spain

[P1.113] Online transcranial direct current stimulation of the frontal cortex induces dopamine release in the striatum – a spatial and temporal analysis in healthy humans C. Fonteneau*

1 ,2, F. Haesebaert

1 ,2, J. Redoute

3, D. Le Bars

3, N. Costes

3, J. Brunelin

1 ,2, M.F. Suaud-Chagny

1

,2,

1Centre de Recherche en Neurosciences de Lyon, France,

2Centre Hospitalier Le Vinatier, France,


3CERMEP—Imagerie du vivant, France

[P1.114] Motor cortical reorganization and clinical outcomes after stroke: a longitudinal TMS/EEG evaluation M.C. Pellicciari*

1 ,2, S. Bonnì

1, A. Martino Cinnera

1, V. Ponzo

1, E. Casula

1, G. Koch

1 ,3,

1IRCCS Santa Lucia

Foundation, Italy, 2

IRCCS San Giovanni di Dio Fatebenefratelli, Italy, 3

Policlinic Tor Vergata, Italy

[P1.115] A primer on developing interleaved transcranial magnetic stimulation with functional magnetic resonance imaging capability: the UBC experience. R. Ge

1, A. Dipinto

1, L. Barlow

1, E. Macmillan

1, A. Mackay

1, M. Alfonso

2, F. Vila-Rodriguez*

1,

1University of

British Columbia, Canada, 2

PLC Electronic Solutions, Canada

[P1.116] Effects of auricular vagus nerve stimulation on brain activity, cognitive parameters and well-being T. Polak*, C. Stelzer, A. Katzorke, J.B.M. Zeller, M.J. Herrmann, University Clinic Würzburg, Germany

[P1.117] Cortical excitability changes parallel motor fluctuations in subjects with Parkinson’s disease and levodopa-induced dyskinesia F. Turco*

1, A. Canessa

1 ,2, C. Olivieri

1, G. Pezzoli

3, I.U. Isaias

3 ,4,

1Fondazione Europea di Ricerca Biomedica

(FERB Onlus), Italy, 2

University of Genoa, Italy, 3

Centro Parkinson ASST G. Pini-CTO Milan, Italy, 4

University Hospital and Julius-Maximillian-University Wuerzburg, Germany

[P1.118] NIRS observation of changes in brain activity following Low Field Magnetic Stimulation M.L. Rohan*, R.T. Yamamoto, K. Ohashi, Y. Tong, L.M. Hocke, B.B. Frederick, B.M. Cohan, McLean Hospital, USA

[P1.119] Could continuous deep brain stimulation in lateral hypothalamus regulate weight gain? A positron emission tomography and behavioral study in obese rats M. Casquero-Veiga*

1 ,2, M. Llorca-Torralba

4 ,1, E. Berrocoso

4 ,1, M. Desco

3 ,2, M.L. Soto-Montenegro

2 ,1,

1CIBER

de Salud Mental (CIBERSAM), Spain, 2

Instituto de Investigación Sanitaria Gregorio Marañón, Spain,

3Universidad Carlos III de Madrid, Spain,

4University of Cadiz, Spain

[P1.120] Mesoscale cortical mapping reveals region-specific and frequency-dependent changes in a mouse model of electroconvulsive therapy D.B. Jovellar*, J. LeDue, T.H. Murphy, F. Vila-Rodriguez, University of British Columbia, Canada

[P1.121] Efficacy of Transcranial direct current stimulation in the Treatment-Resistant patients who suffer from severe Obsessive-Compulsive disorder K. Najafi

1, T. Najafi*

2, Y. Fakour

3, H. Zarrabi

1, A. Heidarzadeh

1, M. Khalkhali

1, T. Yeganeh

4, H. Farahi

1, M.

Rostamkhani1, S. Shabafroz

2,

1Guilan University of Medical Sciences, Iran,

2Islamic Azad University, Iran,

3Tehran University of Medical Sciences, Razi hospital, Iran,

4Kharazmi University, Iran

[P1.122] Effect of myelin parameters and membrane channel dynamics in the SENN model T. Tarnaud*, E. Tanghe, L. Martens, W. Joseph, Ghent University, Belgium

[P1.123] Strategies for targeting deep brain structures using the TES reciprocity based methods M. Fernandez-Corazza*

1 ,2, S. Turovets

3 ,4, P. Luu

3 ,4, C. Muravchik

1 ,5, D. Tucker

3 ,4,

1National University of La

Plata, Argentina, 2

CONICET, Argentina, 3

University of Oregon, USA, 4

Electrical Geodesics Inc, USA, 5

CIC-PBA, Argentina

[P1.124] Use of reciprocity in TES: ways of choosing the current injection electrodes M. Fernandez-Corazza*

1 ,2, S. Turovets

3 ,4, P. Luu

3 ,4, C. Muravchik

1 ,5, D. Tucker

3 ,4,

1National University of La

Plata, Argentina, 2

CONICET, Argentina, 3

University of Oregon, USA, 4

Electrical Geodesics Inc, USA, 5

CIC-pBA, Argentina

[P1.125] TMS field localization: How anatomy shapes stimulation E.G. Lee*

1 ,2, P. Rastogi

2, R.L. Hadimani

3 ,2, D.C. Jiles

2, J.A. Camprodon

1,

1Harvard Medical School, USA,

2Iowa

State University, USA, 3

Virginia Commonwealth University, USA

[P1.126] Modelling electric fields of transcranial direct current stimulation in children P. Ciechanski*, H. Carlson, S. Yu, A. Kirton, University of Calgary, Canada

[P1.127] Tetrahedral vs hexahedral meshes in tCS realistic head modeling R. Salvador*

1 ,2, J. Banus

1, O. Ripolles

1, P.C. Miranda

2, G. Ruffini

1,

1Neuroelectrics, Spain,

2Universidade de

Lisboa, Portugal

[P1.128] Effects of tissue conductivities in tCS of the motor cortex with different electrode configurations L. Santos

1 ,2, M. Martinho

1 ,2, R. Salvador*

2 ,3, C. Wenger

2 ,4, S. Fernandes

2, O. Ripolles

3, G. Ruffini

3, P.C.

Miranda2,

1Instituto Superior Técnico, Universidade de Lisboa, Portugal,

2Universidade de Lisboa, Portugal,


4Novocure Ltd, Israel

[P1.129] The effects of lesions in E-field distribution during frontoparietal tDCS J. Banús*

1, G. Martens

2, R. Salvador

1 ,3, A. Thibaut

2, O. Ripolles

1, G. Antonopoulos

2, C. Di Perri

2, O. Gosseries

2,


S. Laureys2, G. Ruffini

1,


2University of Liège, Belgium,

3Universidade de Lisboa,

Portugal

[P1.130] Experiments and modelling pinpoint the cortical activation site of TMS I. Laakso*

1, T. Murakami

2, A. Hirata

3, Y. Ugawa

2,


2Fukushima Medical University,

Japan, 3

Nagoya Insitute of Technology, Japan

[P1.132] Implementation and comparison of non-invasive stimulation modalities in the VERTEX simulation tool F.E. Hutchings*, C.B. Thornton, M. Kaiser, Newcastle University, UK

[P1.133] Use of transcranial channel in tDCS for targeted neuromodulation - Assessing neural polarization H. Seo*, H-I. Kim, S.C. Jun, Gwangju Institute of Science and Technology, Republic of Korea

[P1.135] Dynamics in response to focal stimulation in a whole-brain network model of mice A. Spiegler*

1, M. Mohajerani

2, V.K. Jirsa

1,

1Institut de la Santé et de la Recherche Médical, Institut de

Neurosciences des Systèmes UMR_S 1106, Aix-Marseille Université, France, 2

Department of Neuroscience, Canadian Centre for Behavioural Neuroscience (CCBN), University of Lethbridge, Canada

[P1.136] Stimulation activates functionally relevant networks in a network model of the human brain A. Spiegler*

1, E.C.A. Hansen

1, C. Bernard

1, A.R. McIntosh

2, V.K. Jirsa

1,

1Institut de la Santé et de la Recherche

Médical, Institut de Neurosciences des Systèmes UMR_S 1106, Aix-Marseille Université, France, 2

2Rotman Research Institute of Baycrest Center, University of Toronto, Canada

[P1.137] Effect of deep brain stimulation of the amygdala on post-traumatic stress disorder syndrome-induced by contextual fear conditioning in rat: Role of c-Fos protein and corticosterone hormone M. Mokhtari Hashtjin*

1, G. Pirzad Jahromi

2, S.S. Sadr

1, M. Tat

2, D. Javidnazar

1, N. Fakhraei

1, S.

Asalgoo2,

1Tehran University of Medical Sciences, Iran,

2Baqiyatallah University Of Medical Science, Iran

[P1.138] Brainjacking: cyber-security risk in deep brain stimulation L. Pycroft*, S.G. Boccard, J.J. Fitzgerald, A.L. Green, T.Z. Aziz, University of Oxford, UK

[P1.139] Altered functional connectivity of the subthalamus and the bed nucleus of the stria terminalis in obsessive-compulsive disorder M. Cano*

1, P. Alonso

1, I. Martínez-Zalacaín

1, M. Subirà

1, E. Real

1, C. Segalàs

1, J. Pujol

2, N. Cardoner

3, J.M.

Menchón1, C. Soriano-Mas

1,

1Bellvitge University Hospital-IDIBELL, Spain,

2Hospital del Mar, Spain,

3Parc

Taulí Sabadell, Spain

[P1.140] Amygdala DBS for PTSD: 2 years of observations on the first case R.J. Koek*

1 ,2, J-P. Langevin

1 ,2, S.E. Krahl

1 ,2, J.W.Y. Chen

1 ,2, A.D. Kulick

1 ,2, H.N. Schwartz

1, M.A. Mandelkern

1,

D.L. Sultzer1 ,2

, 1Veterans Administration, Greater Los Angeles, USA,

2University of California, Los Angeles,

USA

[P1.141] Deep brain stimulation at the anterior thalamic nuclei modulates frontal alpha asymmetry and emotional responses L. Sun*, M. Polvivaara, J. Peräkylä, K. Lehtimäki, J. Peltola, K.M. Hartikainen, Tampere University Hospital, Finland

[P1.142] The effect of deep brain stimulation on visual scanning of Parkinson’s disease patients S. Tokushige*

1, Y. Terao

1 ,2, S. Matsuda

1, G. Oyama

3, Y. Shimo

3, A. Umemura

3, S. Sekimoto

3, T. Sasaki

1, S.

Inomata-Terada1, A. Yugeta

1, M. Hamada

1, Y. Ugawa

4, N. Hattori

3, S. Tsuji

1,

1The University of Tokyo, Japan,

2Kyorin University, Japan,

3Juntendo University, Japan,

4Fukushima Medical University, Japan

[P1.143] Deep brain stimulation: reliable change in executive function and mood T. Cartmill*

1, R. Bittar

1 ,2, G. Youssef

1, T. Perkins

2, L.K. Byrne

1 ,2,

1Deakin University, Australia,

2Precision Brain

Spine and Pain Centre, Australia

[P1.144] Effects of GSM 900 MHz signal on the spectral power in resting electroencephalogram B. Selmaoui*

1, L. Cherif

2, R. Ghosn

1, L. Hugueville

2,

1INERIS-UPJV, France,

2UPMC-Univ Paris6, France

[P1.145] The effect of subthalamic deep brain stimulation on executive and memory functions in Parkinson's disease G. Demeter*

1 ,2, P. Pajkossy

1 ,2, A. Szollosi

1, A. Lukács

1, I. Valálik

1, M. Racsmány

1 ,2,

1Budapest University of

Technology and Economics, Hungary, 2

Hungarian Academy of Sciences, Hungary

[P1.146] Oscillatory neural representations in the thalamus predict neuropathic pain relief by deep brain stimulation Y. Huang*

1, A. Green

2, J. Hyam

2, J. Fitzgerald

2, T. Aziz

2, S. Wang

1,

1Suzhou Institute of Biomedical Engineering

and Technology, Chinese Academy of Sciences, China, 2

University of Oxford, John Radcliffe Hospital, UK

[P1.147] A causal role of the frontopolar cortex in effort preferences A. Soutschek*, T.A. Hare, C.C. Ruff, P.N. Tobler, University of Zurich, Switzerland


[P1.148] Pulse width settings in ventral intermediate nucleus stimulation for essential tremor patients - Is less more? A-S. Moldovan*, N. Meumertzheim, C. Trenado, C.J. Hartmann, J. Vesper, A. Schnitzler, S.J. Groiss, Heinrich-Heine University Düsseldorf, Germany

[P1.149] Which white matter bundles are associated with treatment efficacy in deep brain stimulation of the ventral internal capsule for OCD and MDD? L.C. Liebrand*

1 ,2, M.W.A. Caan

1 ,2, P.R. Schuurman

1 ,2, P. van den Munckhof

1 ,2, D. Denys

1 ,3, G.A. van Wingen

1

,2,

1Academic Medical Center, The Netherlands,

2Amsterdam Neuroscience, The Netherlands,

3Netherlands

Institute for Neuroscience, The Netherlands

[P1.150] Effects of ON and OFF subthalamic nucleus-DBS on prefrontal cortex activation during a cognitive task: An fNIRS study M. Muthalib*

1 ,2, M. Muthuraman

3 ,4, G.K. Kerr

5, L.K. Byrne

1, R.G. Bittar

6 ,1, G. Deuschl

3, S. Perrey

1,

1Deakin


University of Montpellier, France, 3

Christian-Albrechts University, Germany, 4

Johannes-Gutenberg-University Hospital, Germany,

5Queensland University of Technology, Germany,

6Precision Brain,

Spine and Pain Centre, Australia

[P1.151] High-density neural interface on softening substrate R.M. Modi*

1, W.V. Voit

1 ,2,

1University of Texas at Dallas, USA,

2Qualia, Inc, USA

[P1.152] Cogntive functions following Deep Brain Stimulation in depression I.O. Bergfeld*

1 ,5, M.H. Mantione

1, H.G. Ruhé

1 ,3, F. Horst

2, P. Notten

2, J. Van Laarhoven

2, P. Van den

Munckhof1, G. Beute

2, P.R. Schuurman

1, D. Denys

1 ,4,

1University of Amsterdam, The Netherlands,

2St.

Elisabeth Hospital, The Netherlands, 3

University Medical Center Groningen, The Netherlands, 4

Netherlands Institute for Neurosciences, The Netherlands,

5Amsterdam Brain and Cognition, The Netherlands

[P1.153] Rescue leads for suboptimal results following deep brain stimulation for Parkinson's disease A. Fazl*, M.H. Pourfar, A. Mogilner, NYU Langone Medical Center, USA

[P1.154] Deep brain stimulation (DBS) for treatment resistant depression (TRD): 5 year follow up M.A. Cristancho*

1, M.T. Bhati

2, J.P. O'Reardon

3, G.H. Baltuch

1,

1University of Pennsylvania, USA,

2Stanford

University, USA, 3

VA Medical Center, USA

[P1.155] Modulation of voice and speech parameters after subthalamic nucleus deep brain stimulation in Parkinson's disease M. Fournet*

1 ,2, S. Catalano Chiuvé

1, S. Momjian

1, P.R. Burkhard

1 ,2, M. Laganaro

2,

1Geneva University

Hospital, Switzerland, 2

University of Geneva, Switzerland

[P1.156] The outcome after deep brain stimulation in treatment resistant obsessive-compulsive disorder K. Järventausta*

1, E. Leinonen

1 ,2, K. Lehtimäki

1,

1Tampere University Hospital, Finland,

2University of

Tampere, Finland

[P1.157] Decisional impulsivity and the associative-limbic subthalamic nucleus in obsessive-compulsive disorder: subthalamic stimulation and intrinsic functional connectivity V. Voon*

1, F. Droux

2, L. Morris

1, S. Chabardes

2, T. Bougerol

2, O. David

2, P. Krack

2, M. Polosan

2,

1University of

Cambridge, UK, 2

University of Grenoble Alpes, France

[P1.158] Target selection in subcallosal cingulate deep brain stimulation: a prospective, connectomic-based method P. Riva-Posse*, K.S. Choi, A.L. Crowell, R.E. Gross, H.S. Mayberg, Emory University School of Medicine, USA

[P1.159] Reflex saccades' alterations can estimate long-term motor symptoms' progression in DBS STN and MED Parkinson's disease patients S. Szlufik*

1, A. Przybyszewski

2, J. Dutkiewicz

1, P. Habela

2, M. Geremek

1, T. Mandat

3, D.

Koziorowski1,

1Medical University of Warsaw, Poland,

2Polish Japanese Academy of Information Technology,

Poland, 3

Institute of Psychiatrics and Neurology, Poland

[P1.160] Subthalamic nucleus deep brain stimulation surgery in Parkinson’s disease – longitudinal behavioral and cognitive assessment M. Sousa*

1, F. Moreira

1, N. Canário

2, M. Castelo-Branco

2, C. Januário

1,

1Coimbra Hospital and Universitary

Centre, Portugal, 2

University of Coimbra, Portugal

[P1.161] Direct improvement of levodopa induced dyskinesia by interleaving stimulation in subthalamic nucleus area J. Youn*

1 ,2, K.R. Cho

1 ,2, S. Lee

1 ,2, J-I. Lee

1 ,2, J.W. Cho

1 ,2,

1Sungkyunkwan University School of Medicine,

Republic of Korea, 2

Samsung Medical Center, Republic of Korea

[P1.162] Neuromodulation application in cognitive deficits in TBI/concussion M. Ahmed*

1 ,2, J. Long

3, N. Karkhanehchin

3,

1UC San Diego, USA,

2Hoag Neuroscience Institute, USA,


3Memory & Concussion Center, USA

[P1.163] Variability of TMS motor evoked potentials: possible role of premotor cortex A.V. Chervyakov, D.O. Sinitsyn, I.S. Bakulin, L.A. Chernikova, N.A. Suponeva, M.A. Piradov, A. Poydasheva*, Research Center of Neurology, Russia

Poster Sessions 2 Tuesday, 7th March 2017 at 12:00-13:30

[P2.001] Long-term effect of transcranial random noise stimulation (tRNS) on inhibitory control C. Brevet-aeby*

1 ,2, C. Padovan

1 ,2, E. Poulet

1 ,2, J. Brunelin

1,

1Centre Hospitalier Le Vinatier, France,

2Service

de Psychiatrie des urgences, France, 3

Service consultation mémoire, France, 4

Brain Dynamics and Cognition Team, France

[P2.002] Effects of HD-tDCS and crossed-facilitation on interhemispheric interactions M. Muthalib*

1 ,2, V. Cabibel

1, J. Rothwell

3, W.P. Teo

2, S. Perrey

1,


2Deakin


University College London, UK

[P2.003] The neurophysiological connectivity changing in patients with depression is depends on the anodal stimulation area K. Nishida*

1, R. Pascual-Marqui

1 ,2, M. Yoshimura

1, S. Ikeda

1, S. Ueda

1, Y. Koshikawa

1, A. Onohara

1, K.

Katsura1, R. Ishi

3, T. Kinoshita

1,

1Kansai Medical University, Japan,

2University of Zurich, Switzerland,

3Osaka

University Graduate School of Medicine, Japan

[P2.004] Transcranial direct current stimulation (tDCS) improves cognitive-motor performance in older adults with cerebral microvascular disease B. Manor*

1 ,3, J. Zhou

1 ,3, A. Lo

1 ,3, R. Harrison

1, T. Granger

1, H. Zhu

1, T. Travison

1 ,3, A. Pascual-Leone

2 ,3, L.A.

Lipsitz1 ,3

, 1Institute for Aging Research, USA,

2Beth Israel Deaconess Medical Center, USA,

3Harvard Medical

School, USA

[P2.005] Plan for the worst, hope for the best: towards individualising stimulation and experimental parameters in tDCS S. Esterer*, L. Rountree, T. Redmond, D.J. McGonigle, Cardiff University, UK

[P2.006] Transcranial direct current stimulation may enhance decision making in gambling disorder: A preliminary double-blind sham-controlled study S. Aksu*

1, A.Z. Soyata

1, P. İşçen

1, S. İçellioğlu

2, K.T. Saçar

1, G. Aşçı

1, S. Karamürsel

3,

1Istanbul University,

Turkey, 2

T.C. Istanbul Kültür University, Turkey, 3

Istinye University, Turkey

[P2.007] Boosted language: anodal tDCS over Broca's area enhances linguistic comprehension A. Vergallito*

1, B. Giustolisi

1, E. Varoli

1, C. Cecchetto

2 ,1, L.J. Romero Lauro

1,

1Università degli Studi di Milano-

Bicocca, Italy, 2

Université de Paris 8 & CNRS, France

[P2.008] tDCS provokes sustainable changes in EEG and reorganizes autonomic modulation of heart rate A.V. Ashikhmin*

1, A.Y. Shishelova

1 ,3, R.R. Aliev

1 ,2,

1Moscow Institute of Physics and Technology, Russia,

2Institute of Theoretical and Experimental Biophysics, Russia,

3Pirogov Russian National Research Medical

University, Russia

[P2.009] Acute and chronic noradrenergic effects on cortical excitability in healthy humans M.F. Kuo*

1, H.I. Kuo

1 ,2, W. Paulus

2, G. Batsikadze

4, A. Jamil

1, M. Nitsche

1 ,3,

1Leibniz Research Institute for

Working Environment and Human Factors, Germany, 2

Georg-August-University Göttingen, Germany,

3University Medical Hospital Bergmannsheil, Germany,

4University of Duisburg-Essen, Germany

[P2.011] Multi-session transcranial direct current stimulation (tDCS) improves the physiologic complexity of dual-task postural control in functional-limited older adults J. Zhou

1 ,2, L. Lipsitz

1 ,2, B. Manor*

1 ,2,

1Hebrew Senior Life Institute for Aging Research, USA,

2Harvard Medical

School, USA

[P2.012] Effects of transcranial direct current stimulation (tDCS) over right posterior parietal cortex (PPC) on attention function in healthy young adults O. Lo

1 ,2, P. van Donkelaar

3, L.S. Chou

2, B. Manor*

1,

1Institute for Aging Research, USA,

2University of Oregon,

USA, 3


[P2.013] Combining tDCS with a task to reduce impulsivity in a clinical population K. Lim*

1 ,2, B. Nelson

2 ,3, G. Lamberty

2 ,3, C. Gilmore

1 ,2,

1Defense Veterans Brain Injury Center, USA,

2Minneapolis VA Medical Center, USA,

3University of Minnesota, USA


[P2.014] Preliminary results of efficacy and cognitive affects of cathodal transcranial direct current stimulation for the treatment of epilepsy W.Y. Luo, J. Ding*, Y.J. Zhang, Y. Feng, W.F. Peng, X. Wang, Fudan University, China

[P2.016] Using transcranial electrical stimulation (TES) motor threshold to potentially determine individual transcranial direct current stimulation (tDCS) dosing B.W. Badran*

1, E. Kofmehl

1, J.J. Borckardt

1, M. Bikson

1, C. Mullins

1, P. Summers

1, M.S. George

1,

1Medical

University of South Carolina, USA, 2

The City College of New York, USA, 3

Ralph H. Johnson VA Medical Center, USA

[P2.017] Effect of transcranial direct current stimulation over primary motor cortex on static balance in healthy individuals H. Pasin Neto

1 ,3, L.A.C. Grecco

2, N.A.C. Duarte

3, L.V.F. Oliveira

3, C.S. Oliveira*

3,

1Universidade de Sorocaba,

Brazil, 2

Pediatric Neurostimulation Center, Brazil, 3

Universidade Nove de Julho, Brazil

[P2.018] Effects of transcranial direct current stimulation combined with treadmill training on functional mobility in stroke survivors A.J.L. Dumont

1, R.D. Lazzari

1, J.B.P. Lopes

1, R.C.F. Moura

1, H. Pasin Neto

1 ,2, L.V.F. Oliveira

1, C.S.

Oliveira*1,

1Universidade Nove de Julho, Brazil,

2Universidade de Sorocaba, Brazil

[P2.020] Appliance of tDCS for the treatment ASD in children. The methodology of individual approach. I.A. Nikitin, I.O. Efimov*, O.I. Firsenkov, Doctrine Clinic (Prognoz Group), St.Petersburg: child neurology and psychiatry, rehabilitation, Russia

[P2.022] Fronto-temporal transcranial direct-current stimulation reduces auditory verbal hallucinations and n-acetylaspartate-glutamate level in the left temporoparietal junction in patients with schizophrenia M. Psomiades*

1 ,2, M. Mondino

1 ,2, E. Poulet

1 ,2, F. Haesebaert

1 ,2, M.F. Suaud-Chagny

1 ,2, J. Brunelin

1 ,2,

1Lyon

Neuroscience Research Center, France, 2

University Lyon, France, 3

University Lyon 1, France

[P2.023] Assessing stimulation effects induced by tDCS using MEG S. Jang*, D. Kim, H. Cho, M. Kwon, S.C. Jun, Gwangju Institute of Science and Technology, Republic of Korea

[P2.024] Development of a low-cost, open-source transcranial direct-current stimulation device (tDCS) for the modulation of brain rhythms D.L. Henao*

1, G. Monsalve

2, M.G. Navarrete

1, M. Le Van Quyen

3, M.A. Valderrama

1,

1Universidad de los

Andes, Colombia, 2

Fundación Santa Fe de Bogotá, Colombia, 3

Université Pierre et Marie Curie, France

[P2.026] Effect of transcranial direct current stimulation on cognitive function in tobacco smokers: a preliminary study A. Alatawi*, A. Alhussien, T. Almusned, M. Alohali, F. Alghamdi, S. Habib, S. Bashir, King Saud University, Saudi Arabia

[P2.027] Effects of transcranial direct-current stimulation on laparoscopic surgical skill acquisition: a randomized clinical trial P. Ciechanski*, A. Cheng, O. Damji, S. Lopushinsky, K. Hecker, Z. Jadavji, A. Kirton, University of Calgary, Canada

[P2.028] Diagnostic transcranial magnetic stimulation in children with acute inflammatory demyelinating polyneuropathy V.B. Voitenkov*, N.V. Skripchenko, A.V. Klimkin, Scientific Research Institute of Children’s Infections, Russia

[P2.029] Transcranial magnetic stimulation biomarkers in adolescent depression P.E. Croarkin*

1, C. Lewis

1, J. Vande Voort

1, J. Kohli

1, J. Lee

2, Z.J. Daskalakis

2,

1Mayo Clinic, USA,

2Centre for

Addiction and Mental Health, Canada

[P2.030] Gait disturbance is correlated with central cholinergic dysfunction in patients with early Parkinson's disease E.S. Oh*, Y.G. Lim, J.Y. Ham, A.Y. Lee, Chungnam National University Hospital, Republic of Korea

[P2.031] Clinical factors affecting the resting motor threshold in preoperative navigated TMS motor mapping N. Sollmann*

1, N. Tanigawa

2, L. Bulubas

1, F. Ringel

1, B. Meyer

1, S.M. Krieg

1,

1Technische Universität

München, Germany, 2

University of Oxford, UK

[P2.032] Repetitive brain stimulation induces long-term plasticity across patient populations and spatial scales C.K. Keller*

1 ,2, W.W. Wu

1 ,2, R.W. Wright

1 ,2, N.I. Ichikawa

5, J.H. Huemer

6, M.W. Wong

1 ,2, A.Y. Yee

1 ,2, E.S.

Shpigel1 ,2

, L.M. McTeague4, M.F. Fini

4,

1Stanford University, USA,

2VA Palo Alto Medical Center, USA,

3Medical University of South Carolina, USA,

4North Shore LIJ-Hofstra Medical Center, USA,

5Hiroshima

University, USA, 6

Medical University of Vienna, USA


[P2.033] Decision making and emotional processing following Theta Burst Transcranial Magnetic Stimulation on medial prefrontal cortex. K. Konikkou*

1, N. Konstantinou

1 ,2, K. Fanti

1,

1University of Cyprus, Cyprus,

2Cyprus University Of Technology

(TEPAK), Cyprus

[P2.034] Vocal accelerometer recording of TMS evoked language disturbances: preliminary study for awake surgery application J. Leote*

1 ,3, J. Valls-Solé

3, J. Costa

2 ,3, J. Casanova-Molla

3, L. Oleaga

3, J. Fonseca

2, R.G. Nunes

2, H.A.

Ferreira2,

1Hospital Garcia de Orta, Portugal,

2University of Lisbon, Portugal,

3University of Barcelona, Spain

[P2.035] Effect of subthreshold paired associative stimulation during voluntary contraction on motor learning T. Sasaki*

1, S. Tokushige

1, N. Togashi

1, S. Inomata-Terada

1, Y. Terao

2, Y. Ugawa

3, M. Hamada

1,

1The

University of Tokyo, Japan, 2

Kyorin University School of Medicine, Japan, 3

Fukushima Medical University, Japan

[P2.036] Global structural and effective connectivity in patients with chronic disorders of consciousness. O. Bodart

1, E. Amico

1, S. Wannez

1, F. Gomez

1 ,3, S. Casarotto

2, M. Rosanova

2, A.G. Casali

2 ,4, O. Gosseries

1 ,5, S.

Laureys1, M. Massimini

2 ,6, G. Martens*

1,

1University of Liege, Belgium,

2University of Milano, Italy,

3Universidad central de Colombia, Colombia,

4Federal university of Sao Paolo, Brazil,

5University of Wisconsin,

USA, 6

Fondazione Don Carlo Gnocchi, Italy

[P2.037] Human brain connectivity in response to paired pulse TMS paradigm M. Alomar*

1, W. Yoo

1, M. Vernet

1, G. Murtaza

1, A. Rotenberg

1, S. Bashir

1,

1King Saud University, Saudi

Arabia, 2

Hallym University Sacred Heart Hospital, Republic of Korea, 3

Beth Israel Deaconess Medical Center, USA,

4Boston Children's Hospital, USA

[P2.038] Repetitive transcranial magnetic stimulation ameliorates anxiety-like behavior and impaired sensorimotor gating in a rat model of post-traumatic stress disorder Z.W. Peng*, F. Xue, H.N. Wang, Q.R. Tan, Xijing Hospital, Fourth Military Medical University, China

[P2.039] The neuroplastic effects of multisite stimulation - a continuous theta burst investigation M. Do*, M. Kirkovski, C. Davies, P.G. Enticott, L.K. Byrne, Deakin University, Australia

[P2.040] Does the presence of a TMS-evoked MEP predict walking speeds in individuals with chronic stroke? S. Madhavan*, M. Yerrapothu, A. Williams, A. Gradowska, The University of Illinois at Chicago, USA

[P2.041] A system of TMS maintenance for depressed mood M. Rybak*

1, E. Kelly

1, S. Erger MEd

1, S. Pridmore

1 ,2,

1Saint Helen's Private Hospital, Australia,

2University of

Tasmania, Australia

[P2.042] Sequential Theta burst stimulation changes language function after stroke - Preliminary analysis in Chinese survivors W. He*

1, K. Lee

1, T. Leung

2 ,1, H. Leung

2 ,1, Q. Zhang

3 ,4, L. Wong

2 ,1,

1The Chinese University of Hong Kong,

Hong Kong, 2

Prince of Wales Hospital, Hong Kong, 3

Capital Medical University, China, 4

China Rehabilitation Research Center, China

[P2.043] The efficacy of selective transcranial magnetic stimulation with functional near-infrared spectroscopy and intensive speech therapy on individuals with post-stroke aphasia T. Hara*

1, M. Abo

1, K. Kakita

2,

1The Jikei University School of Medicine, Japan,

2Kyoto Ohara Memorial

Hospital, Japan

[P2.044] Towards a more targeted rTMS treatment for late-life depression: age-specific morphometric variance of left dorsolateral prefrontal cortex H. Lu, Chinese University of Hong Kong, Hong Kong

[P2.045] Impaired rTMS-induced short-term neuroplasticity in restless legs syndrome: a pilot study G. Lanza*

1, M. Cantone

1, B. Lanuzza

1, D. Aricò

1, F.I.I. Cosentino

1, M. Pennisi

2, R. Bella

3, G. Pennisi

3, R.

Ferri1,

1I.R.C.C.S. “Oasi Maria SS.”, Italy,

2Emergency Hospital “Cannizzaro”, Italy,

3University of Catania, Italy

[P2.046] Brain-stimulation for arm recovery after stroke - protocol for a randomised clinical trial E.C.C. van Lieshout*, J.M.A. Visser-Meily, H.B. van der Worp, S.F.W. Neggers, R.M. Dijkhuizen, UMC Utrecht, The Netherlands

[P2.047] 5Hz repetitive transcranial magnetic stimulation (rTMS)-effects on cortical excitability and speech and swallowing functions in stroke patients I.K.Y. Cheng*

1, E.M.L. Yiu

1, L.S.W. Li

2, K.M.Y. Chiu

2, C.S. Wong

2, K.M.K. Chan

1,

1The University of Hong Kong,

Hong Kong, 2

Tung Wah Hospital, Hong Kong

[P2.048] Effect of repetitive transcranial magnetic stimulation on the structural connectome in patients with major depression Z. Deng

1 ,2, S.W. Davis

2, G. Asturias

2, M. Glidewell

2, C. Liston

3, S.H. Lisanby

1 ,2, M.J. Dubin*

3,

1National


Institutes of Health, USA, 2

Duke University, USA, 3

Weill Cornell Medical College, USA

[P2.049] The effects of rTMS on LDAEP and prediction of treatment response in depression S.M. Lee*, K.I. Jang, J.H. Chae, The Catholic University of Korea, Republic of Korea

[P2.050] EEG under TMS-induced SP reveals inhibitory effects of low-frequency rTMS on the primary motor cortex F. Jin, J. Jin, Y. Li, X. Wang, Z. Liu, T. Yin*, Chinese Academy of Medical Sciences Peking Union Medical College, China

[P2.051] Matching action observation to action execution M. Soriano*

1, A. Cavallo

1, C. Becchio

1 ,2,

1University of Turin, Italy,

2Italian Institute of Technology, Italy

[P2.052] 10 and 20 Hz and theta burts rTMS stimulation in the treatment of neuropathic orofacial pain J.F. Fricova*, R.R. Rokyta, Charles University, Czech Republic

[P2.053] In search of optimal site for 10 Hz rTMS depression treatment: a clinical and physiological comparison V. Valiulis*

1, K. Valaviciute

2, K. Dapsys

1 ,2, G. Gerulskis

1, A. Siurkute

1, V. Maciulis

1,

1Republican Vilnius

Psychiatric Hospital, Lithuania, 2

Vilnius University, Lithuania

[P2.054] Preliminary results from a randomized sham-controlled trial of augmentative Neuro-navigated right-dorsolateral prefrontal cortex low-frequency repetitive transcranial magnetic stimulation for antidepressant non-responding Bipolar depression A.D.P. Mak*, S.S.M. Chan, L.C.W. Lam, W.C.W. Chu, A. Chan, C.M.C. Leung, S. Lee, The Chinese University of Hong Kong, Hong Kong

[P2.055] Neurobiological mechanisms of deep transcranial magnetic stimulation (dtms): a systematic review L. Schmittwilken

1, M. Schuchinsky

2, K.K. Kedzior*

1,


2University of Limerick,

Ireland

[P2.056] Magnetic focusing by magnetic shielding for Non-Invasive Brain Stimulation Q. Meng

1 ,2, M. Cherry

1, X. Du

1, H. Lu

2, E. Hong

1, Y. Yang

2, F-S. Choa*

1,

1University of Maryland, USA,

2National Institutes of Health, USA

[P2.057] Spike-timing dependent plasticity at spinal motoneurons A. Yamashita*

1 ,2, T. Murakami

3, S. Kadowaki

3, K. Yoshida

3, E. Ito

3, N. Matsuda

3, F. Chang

3, N. Hattori

1, I.

Miyai1, Y. Ugawa

3,

1Neurorehabilitation Research Institute, Morinomiya Hospital, Japan,

2Bobath Memorial

Hospital, Japan, 3


[P2.059] More is not always better: impact of different intensities of intermittent theta burst stimulation in prefrontal cortex using TMS-EEG S.W. Chung*

1, N.C. Nigel

2, K.E. Hoy

1, P.B. Fitzgerald

1,

1Monash Alfred Psychiatry Research Centre, Australia,

2Brain and Mental Health Laboratory, Australia

[P2.060] Different roles of pre-SMA and SMA in human visuomotor sequence learning: a TMS study T. Shimizu*

1 ,2, R. Hanajima

1, R. Tsutsumi

1, Y. Shirota

2, N. Tanaka

2, M. Hamada

2, Y. Ugawa

3,

1Kitasato

Medical University, Japan, 2

University of Tokyo, Japan, 3


[P2.061] Paired associative quadripulse stimulation (PAS-QPS) - a new protocol combining homo- and hetero-synaptic plasticity W. Wiratman*

1 ,2, T. Murakami

1, S. Kobayashi

1, H. Enomoto

1, Y. Ugawa

1,

1Fukushima Medical University,

Japan, 2

Universitas Indonesia, Indonesia

[P2.062] Low intensity rTMS does not change excitability in cortical layer V as measured by in vivo local field potentials M. Sykes*

1 ,2, A. Tang

2, J. Rodger

2, J.N.J. Reynolds

1,

1University of Otago, New Zealand,

2University of

Western Australia, Australia

[P2.063] Repetitive navigated αTMS in treatment-resistant schizophrenia H. Tuppurainen*

1 ,2, S. Määttä

3, M. Vanhanen

1 ,2, M. Könönen

3, P. Julkunen

1 ,3, K. Aho-Mustonen

1 ,2, S.

Hyvärinen1 ,2

, O. Vaurio1 ,2

, M. Joensuu1 ,2

, E. Repo-Tiihonen1 ,2

, E. Mervaala1, J. Tiihonen

1,

1University of

Eastern Finland, Finland, 2

Niuvanniemi Hospital, Finland, 3

Kuopio University Hospital, Finland, 4

Karolinska Institutet, Sweden

[P2.064] Effect of repetitive magnetic stimulation on the expression of endocannabinoid system related genes in cultured neuron S.S. Xue*, C.H. Zhou, F. Xue, Z.W. Peng, H.N. Wang, Xijing Hospital, Fourth Military Medical University, China

[P2.065] Controlled stimulation of deep brain areas using navigated TMS with a standard coil. C.M. Thordstein*, O. Thorell, Center for Social and Affective Neouroscience, Sweden


[P2.066] Preliminary results: resting-state fMRI correlations between left dorsolateral prefrontal cortex and subgenual cingulate and the relationship with repetitive transcranial magnetic stimulation treatment response H.J. Hopman*

1, S.F.W. Neggers

2, L.C.W. Lam

1, A.D.P. Mak

1, S.S.M. Chan

1,

1The Chinese University of Hong

Kong, Hong Kong, 2

University Medical Center Utrecht, The Netherlands

[P2.067] Experience of complex application of neuromodulation technologies in cases of severe cerebral lesions I.V. Martynov*

1, V.P. Ilyichev

1, A.L. Gorelik

2, A.G. Naryshkin

3,

1Voronezh State Medical University named

after N.N. Burdenko (Voronezh, Russia), Russia, 2

The St. Petersburg Bekhterev Psychoneurological Research Institute, Russia,

3North-Western State Medical University named after I.I.Mechnikov, Russia,

4Remedial

center & Alternativa & Voronezh, Russia

[P2.068] Screen angle and viewing preference effect corticospinal excitability during action observation M. Riach*, P.S. Holmes, D.J. Wright, Manchester Metropolitan University, UK

[P2.069] Directing gaze behaviour during action observation modulates corticospinal excitability D.J. Wright*, G. Wood, Z.C. Franklin, B. Marshall, M. Riach, P.S. Holmes, Manchester Metropolitan University, UK

[P2.071] Can TMS of forearm muscles improve prediction of dexterity after stroke? C.D. Bakker*

1, M. Massa

1, T. Feuth

1, J. Pasman

1, A.A. van Kuijk

3 ,1, G. Kwakkel

2, A.C.H. Geurts

1, D.

Stegeman1,

1Radboud University Medical Centre, The Netherlands,

2VU University Medical Center, The

Netherlands, 3

Tolbrug Rehabilitation Centre, The Netherlands

[P2.072] A simultaneous EEG and TMS study investigating mirror neuron system activity when inferring intentions E.J. Cole*

1, N.E. Barraclough

1, P.G. Enticott

2,

1The University of York, UK,

2Deakin University, Australia

[P2.073] Differential effects of TBS over DLPFC on the theory of mind related to personality factors E.M. Marron*, D. Redolar-Ripoll, C. Portugal, A. Penellas, J. Castillo, R. Viejo-Sobera, Universitat Oberta de Catalunya, Spain

[P2.074] Transcranial magnetic stimulation as a neurophysiological biomarker in spinocerebellar ataxia P. Davila-Pérez

1 ,2, A. Jannati*

1 ,2, S. Wakefield

1 ,2, B. Manor

1 ,2, P. Greenstein

1 ,2, A. Pascual-Leone

1 ,2,

1Beth

Israel Deaconess Medical Center, USA, 2

Harvard Medical School, USA

[P2.075] Reproducibility of intermittent theta-burst, paired-pulse, and single-pulse transcranial magnetic stimulation measures in older clinical populations P.J. Fried*, A. Jannati, P. Davila-Pérez, A. Pascual-Leone, Harvard Medical School, USA

[P2.076] Corticospinal facilitation is enhanced post eccentric aerobic cycling in healthy subjects J.A. Walsh*, P.J. Stapley, D.J. McAndrew, University of Wollongong, Australia

[P2.077] Short duration strength training increases corticospinal efficacy in healthy subjects D.J. McAndrew*, D.M. Hurley, J.A. Walsh, P.J. Stapley, University of Wollongong, Australia

[P2.078] Practical considerations for transcranial magnetic stimulation in the old-old P. Fernandes, Creighton University School of Medicine, USA

[P2.079] Functional improvement of subcortical aphasia after series of repetitive transcranial magnetic stimulation A. Tiksnadi, Universitas Indonesia, Indonesia

[P2.080] Response to high-frequency repetitive transcranial magnetic stimulation over left dorsolateral prefrontal cortex is unaffected by number of treatment sessions in major depression: a systematic meta-analysis of randomized, sham-controlled trials C. Deblieck*

2, M. Wampers

1 ,2, P. Sienaert

1 ,2, C. Bervoets

1 ,2,

1KU Leuven, Belgium,

2UPC KU Leuven Z.org,

Belgium

[P2.081] Long-term paired associative stimulation - A potential therapy for spinal cord injury patients A. Shulga*

1 ,2, A. Zubareva

1 ,2, P. Lioumis

1 ,2, E. Kirveskari

1 ,2, S. Savolainen

3, A. Ylinen

1 ,2, J.P. Mäkelä

1

,2,

1Helsinki University Central Hospital, Finland,

2University of Helsinki, Finland,

3Validia Rehabilitation

Center, Finland

[P2.082] Global patterns of network connectivity in schizophrenia: A TMS-EEG network study J. Naim-Feil*

1 ,2, D. Freche

1 ,2, M. Rubinson

1, A. Grinshpoon

3 ,4, A. Peled

3 ,4, E. Moses

1, N. Levit-Binnun

2, E.

Weinreb1,

1The Weizmann Institute of Science, Israel,

2Interdisciplinary Center (IDC), Israel,

3Sha'ar Menashe

Mental Health Center, Israel, 4

Israel Institute of Technology, Israel

[P2.083] Safety, tolerability and compliance of patients receiving long-term rTMS for chronic pain S. Gulati*

1, A. Mavrianou

1 ,2, P. Sacco

1 ,2, T. Nurmikko

1 ,2,

1Walton Centre NHS Foundation Trust, UK,

2Pain

Research Institute, University of Liverpool, UK


[P2.084] Optimal rTMS site on freezing of gait in Parkinson's disease: A pilot study S.J. Kim*

1, S.Y. Kang

2, J.S. BaiK

1,

1Inje University College of Medicine, Republic of Korea,

2Hallym University

College of Medicine, Republic of Korea

[P2.085] Repetitive transcranial magnetic stimulation treatment in Alzheimer's disease J. Lee*, E. Oh, E.H. Sohn, A.Y. Lee, Chungnam national university hospital, Republic of Korea

[P2.086] Dissecting direct and indirect pathways between ventral premotor cortex and the spinal cord by transcranial magnetic stimulation K.L. Bunday*

1, M. Pereira

1, M. Davare

1 ,2,


2KU Leuven, UK

[P2.087] The effect of voluntary contraction on the direction of the wrist movement induced by focal tms M. Fernàndez-Lobera*, R. Arca, J. Valls-Solé, University of Barcelona, Spain

[P2.088] Multi-locus TMS: electronic control of the stimulation location with large thin overlapping coils L.M. Koponen*, J.O. Nieminen, R.J. Ilmoniemi, Aalto University, Finland

[P2.089] Effect of ipsilesional anodal tDCS with contralesional low-frequency rTMS for post-stroke motor impairment Y-H. Kim*

1, E. Park

1, J-S. Lee

2, W-H. Chang

1, A. Lee

1,

1Sungkyunkwan University, Republic of Korea,

2Korea

Advanced Institute of Science and Technology, Republic of Korea

[P2.090] Multi-locus transcranial magnetic stimulation of the primary motor cortex J.O. Nieminen*

1 ,2, L.M. Koponen

1 ,2, N. Mäkelä

1 ,2, R.J. Ilmoniemi

1 ,2,


2Helsinki

University Hospital, Finland

[P2.091] Towards brain-state dependent transcranial magnetic stimulation: Targeting the phase of oscillatory neocortical activity with singe-pulse TMS M.G. Safeldt*

1, L. Tomasevic

1, A. Karabanov

1, H. Siebner

1, K.H. Madsen

1 ,2,

1Copenhagen University Hospital,

Denmark, 2

Technical University of Denmark, Denmark

[P2.092] Should I stop or should I go? A differential role of PMD And SMA in action inhibition, a TMS study S. Parmigiani*

1, B. Zattera

1, L. Cattaneo

2,

1University of Trento, Italy,

2University of Verona, Italy

[P2.093] Comparison of local sensory effects associated with real and sham TMS T. Nurmikko*, A. Mavrianou, B. Frank, P. Sacco, The Walton Centre NHS Foundation Trust, UK

[P2.094] Increase of sleep spindle density induced by rTMS for major depression T. Izuno*

1 ,2, T. Saeki

3, N. Hirai

4, M. Nakamura

1 ,2,

1Kanagawa Psychiatric Center, Japan,

2Showa University

School of Medicine, Japan, 3

Yokohama City University School of Medicine, Japan, 4

Tokyo Medical and Dental University, Japan

[P2.095] Neuro-cardiac-guided tms (ncg tms): probing dlpfc-sgacc connectivity using heart rate T.A. Iseger*

1 ,2, M. Arns

2 ,3,

1Utrecht University, The Netherlands,

2Research Institute Brainclinics, The

Netherlands, 3

neuroCare Group, Germany

[P2.096] Neurophysiological effects of low and high frequency rTMS on long latency auditory evoked potentials C. Nathou*

1 ,2, E. Duprey

1 ,2, G. Simon

3, A. Razafimandimby

2, E. Leroux

2, S. Dollfus

1 ,2, O. Etard

2 ,4,

1Centre

Esquirol, France, 2

Imagerie et Stratégies Thérapeutiques de la schizophrénie (ISTS), France, 3

UNICAEN, France,

4Service des explorations fonctionnelles du système nerveux, France

[P2.097] Number of pulses or number of sessions? Trajectories of improvement for once-daily vs. twice-daily dorsomedial prefrontal rTMS in major depression L. Schulze

1 ,2, C. Lozano

1 ,2, P. Giacobbe

1 ,2, Z. Daskalakis

2 ,3, D. Blumberger

2 ,3, J. Downar*

1 ,2,

1University

Health Network, Canada, 2

University of Toronto, Canada, 3

Centre for Addiction and Mental Health, Canada

[P2.098] The comparison of rTMS machines from different manufactories on effects of cTBS-related protocols P.Y. Fong*

1, Y.Z. Huang

1 ,2,

1Chang Gung Memorial Hospital, Taiwan,

2Chang Gung University, Taiwan

[P2.099] A randomized comparison of 1 Hz vs. 20 Hz vs. sham dorsomedial prefrontal rTMS for treatment-resistant depression: Preliminary clinical results K. Dunlop*

1 ,3, J. Sheen

3, B. Woodside

2, P. Colton

2, M. Olmsted

2, K. Feffer

3, D.M. Blumberger

2, Z.J.

Daskalakis2, P. Giacobbe

2 ,3, J. Downar

2 ,3,



3MRI-Guided rTMS Clinic, Toronto Western Hospital, Canada

[P2.100] Cortico-cortical and cortico-striatal resting-state functional connectivity differentially predicts response to 10 Hz rTMS and intermittent TBS to the DLPFC K. Dunlop*

1, S.K. Peters

1, P. Giacobbe

1, Z.J. Daskalakis

1, R.W. Lam

1, S.H. Kennedy

1, F. Vila-Rodriquez

1, D.M.

Blumberger1, J. Downar

1,



3MRI-

Guided rTMS Clinic, Toronto Western Hospital, Canada


[P2.101] Adaptation to leftward shifting prisms alters motor inter-hemispheric inhibition E. Martín-Arévalo*

1 ,2, S. Schintu

1 ,2, A. Farné

1 ,4, L. Pisella

1, K.T. Reilly

1,

1Lyon Neuroscience Research Center,

France, 2

University of Granada, Spain, 3

National Institutes of Health, USA, 4

Neuro-immersion & Mouvement et Handicap, France

[P2.102] Corticospinal excitability and cognitive dysfunction in obstructive sleep apnea syndrome P.Á. De Toledo*

1, J.F. Martín-Rodríguez

1, M.I. Asensio-Cruz

2, F. Sanmartino

1, A. Sánchez-Armengol

2, A.

Rodríguez-Baena1, C. Calero-Acuña

2, L. Garrote-Espina

1, C. Carmona-Bernal

2, P. Mir

1 ,3,

1Universidad de

Sevilla, Spain, 2

Hospital Universitario Virgen del Rocío, Spain, 3

Centro de Investigación Biomédica en Red sobre Enfermedades Neurodegenerativas (CIBERNED), Spain

[P2.103] TMS enhances phase-amplitude coupling of neural oscillations S. Glim*

1 ,2, Y.O. Okazaki

1, Y. Nakagawa

1, T. Hanakawa

1 ,4, Y. Mizuno

1 ,4, K. Kitajo

1 ,4,

1RIKEN Brain Science

Institute, Japan, 2

Technical University of Munich, Germany, 3

LMU Munich, Germany, 4

National Center of Neurology and Psychiatry, Japan

[P2.104] A skin capacitor model for the TMS-induced artifact in EEG D. Freche

1 ,2, N. Levit-Binnun

1, W. Weinreb*

2, J. Naim-Feil

2, A. Peled

3 ,4, E. Moses

2,

1Interdisciplinary Center

(IDC) Herzliya, Israel, 2

Weizmann Institute, Israel, 3

Technion, Israel, 4

Sha'ar Menashe Mental Health Center, Israel

[P2.105] Effect of transcranial magnetic stimulation on noxious cold mediated pain modulation in fibromyalgia syndrome S. Tanwar*, B. Mattoo, S. Jain, U. Kumar, R. Dada, R. Bhatia, All India Institute of Medical Sciences, India

[P2.106] Neurostimulation for the treatment of functional neurological disorders: Novel therapeutic strategy or placebo effect? P. Gros*

1, R. Chen

1, A. Feinstein

2, A.E. Lang

1, M.J. Burke

1,

1University Health Network, Canada,

2Sunnybrook

Health Sciences Centre, Canada

[P2.107] Dependence of short-interval intracortical inhibition on conditioning pulse duration R. Hannah*, S. Tremblay, L. Rocchi, J.C. Rothwell, UCL Institute of Neurology, UK

[P2.108] Intervention induced intra-cortical plasticity in hemiparetic children with perinatal stroke H.C. Kuo*, E. Zewdie, P. Ciechanski, A. Kirton, University of Calgary, Canada

[P2.109] Robotic TMS mapping of motor cortex in the developing brain J.G. Grab*, E. Zewdie, H.C. Kuo, A. Giuffre, A. Kirton, University of Calgary, Canada

[P2.110] Safety, feasibility, and efficacy of rTMS for major depression in borderline personality disorder: A 2-case report K. Feffer*

1 ,2, P. Giacobbe

2 ,3, P. Fettes

4, J. Downer

2 ,3,

1Shalvata Mental Health Center, Israel,

2University of

Toronto, Canada, 3

University Health Network, Canada, 4

University of Toronto, Canada

[P2.111] Successful treatment of bipolar depressive disorder patients using transcranial magnetic stimulation: results from an urban TMS clinic R. McMullen*

1, S. Agarwal

1,

1TMS Brain Care, USA,

2NYU Langone Medical Center, USA

[P2.112] Effects of propranolol on cortical excitability: a TMS study A. Miguel-Puga*

1 ,2, G. Villafuerte

1 ,2, O. Arias-Carrión

1,

1Hospital General Dr Manuel Gea Gonzalez, Mexico,

2Universidad Nacional Autonoma de Mexico, Mexico

[P2.113] Scalp-based heuristics for locating the nodes of the salience network for use in neurostimulation A. Mir-Moghtadaei

1, K. Dunlop

1, F. Mansouri

2, P. Giacobbe

3, S.H. Kennedy

1 ,3, R.H. Lam

4, F. Vila-Rodriguez

4,

Z.J. Daskalakis1 ,3

, D.M. Blumberger1 ,3

, J. Downar*1 ,3

, 1Institute of Medical Sciences, Canada,

2Institute of

Biomaterials and Biomedical Engineering, Canada, 3

University Health Network, Canada, 4


[P2.114] rTMS as a treatment for mild traumatic brain injury G. Rutherford*

1, B. Mansouri

1, W. Zhang

1, X. Wang

1, A. Sulieman

1, O. Ranjbar

1, Z. Dastgheib

1, J. Salter

2, B.

Lithgow1, Z. Moussavi

1,

1University of Manitoba, Canada,

2Riverview Health Centre, Canada

[P2.115] The efficacy of paired-associative stimulation for inducing neuroplasticity in motor cortex of healthy individuals: a qualitative review M. Minkovich*

1, R. Zomorrodi

1 ,2, Y. Noda

1 ,2, D.M. Blumberger


1 ,2, T.K. Rajji

1,

1Centre for

Addiction and Mental Health, Canada, 2


[P2.116] Modelling the interactions of ongoing brain activity and transcranial magnetic stimulation of the motor cortex N. Schaworonkow*, J. Triesch, Frankfurt Institute for Advanced Studies, Germany


[P2.117] Influence of instantaneous phase on short-term plasticity induced by a single TMS burst N. Schaworonkow*

1, C. Zrenner

2, D. Desideri

2, P. Belardinelli

2, J. Triesch

1, U. Ziemann

2,

1Frankfurt Institute

for Advanced Studies, Germany, 2

University of Tübingen, Germany

[P2.118] Dual-target rTMS as treatment protocol for Parkinson’s disease L.I. Aftanas*

1 ,2, I.V. Brack

1, K.V. Danilenko

1, K.I. Kulikova

1, S.S. Dzemidovich

1 ,3, B.M. Doronin

3,

1Scientific

Research Institute of Physiology & Basic Medicine, Russia, 2

Novosibirsk State University, Russia, 3

Novosibirsk State Medical University, Russia

[P2.119] Characterising the nature of proactive and reactive inhibition in a task of selective stopping: A TMS study V. Rawji*, R. Tibold, T. Foltynie, M. Jahanshahi, J. Rothwell, University College London, UK

[P2.120] Cortico-cortical excitability is influenced by the phase of oscillatory activity at the time of the stimulus D. Desideri*, P. Belardinelli, C. Zrenner, U. Ziemann, University of Tübingen, Germany

[P2.121] Interhemispheric communication through neuronal coherence revealed by closed-loop EEG-dual-site-TMS M.I. Stefanou*, D. Desideri, P. Belardinelli, C. Zrenner, U. Ziemann, Hertie Institute for Clinical Brain Research, Germany

[P2.122] The neural basis of visual sensitivity investigated with anterior prefrontal TMS J.H. Hobot*

1 ,2, K.S. Sandberg

2, M.W. Wierzchon

1, B.P. Paulewicz

1,

1Jagiellonian University, Poland,

2Aarhus

University Hospital, Denmark

[P2.123] Clinical effects of intermittent theta-burst stimulation of the anterior temporal lobe to promote visual motor integration and perceptual reasoning in pediatric traumatic brain injury: a case study H.Y. Lee*, T.W. Kim, National Traffic Injury Rehabilitation Hospital, Republic of Korea

[P2.124] Modelling of transcranial magnetic stimulation and associated brain activity: use realistic models M. Stenroos*, L.M. Koponen, Aalto University, Finland

[P2.125] Comparison between high vs low frequencies of rtms on major depression symptoms A.I. Buenfil Hernández*, A.C. Rodríguez Cámara, J.A. Moo Estrella, Autonomous Univeristy of Yucatan, Mexico

[P2.126] Low and high frequency repetitive transcranial magnetic stimulation on the quality of sleep in patients with major depression J.A. Moo Estrella*

1, A. Carrillo Sulub

1, A. Buenfil Hernández

1, A. Rodríguez Cámara

1, J. González

Olvera2,

1Autonomous University of Yucatan, Mexico,

2National Institute of Psychiatry Ramon de la Fuente,

Mexico

[P2.127] Diferences in the improve of the cognitive flexibiliy in pacients with major depression using low and high frequencies of repetitive transcranial magnetic stimulation A.C. Rodríguez Cámara*, A.I. Buenfil Hernández, J.A. Moo Estrella, Autonomous University of Yucatán, Mexico

[P2.128] Transcranial magnetic stimulation treatment of depression using a 20 hertz theta burst pulse pattern: a consecutive case series W.F. Stubbeman*, B. Zarrabi, V.E. Ragland, R. Khairkhah, Stubbeman Brain Stimulation Institute, USA

[P2.129] Transcranial magnetic stimulation (TMS) coil designing for high electromagnetic field gradient generation Q. Meng, E. Hong, F-S. Choa*, University of Maryland, USA

[P2.130] Augmenting transcranial magnetic stimulation with administration of exogenous ketones R. Berlow, ABSC, USA

[P2.131] Characterisation of glutamatergic and GABAA mediated neurotransmission in motor and dorsolateral prefrontal cortex using paired-pulse TMS-EEG R. Cash*

4 ,5, Y. Noda

1 ,3, R. Zomorrodi

1, N. Radhu

1 ,4, F. Farzan

1, T.K. Rajji

1 ,2, R. Chen

4, Z.J. Daskalakis

1 ,2, P.B.

Fitzgerald5, D.M. Blumberger

1 ,2,

1Temerty Centre for Therapeutic Brain Intervention, Centre for Addiction

and Mental Health, Canada, 2

Campbell Family Mental Health Research Institute, Centre for Addiction and Mental Health, Canada,


4Toronto Western Research Institute, Canada,

5Monash Alfred Psychiatry Research Centre, Australia

[P2.132] Effects of repetitive transcranial magnetic stimulation on improvement of cognition in elderly patients with cognitive impairment: A systematic review and meta-analysis P.W. Cheng*

1 ,2, S.M. Wong

2, K.Y. Lee

2, P.K. Chan

2, W.F. Yeung

3, W.C. Chan

2,

1Queen Mary Hospital, Hong

Kong, 2

The University of Hong Kong, Hong Kong, 3

The Hong Kong Polytechnic University, Hong Kong

[P2.133] Spatial and temporal extent of single-pulse TMS on single-cell activity in alert macaque monkeys M.C. Romero*, M. Davare, P. Janssen, KU Leuven, Belgium


[P2.134] Validation of a double-coil TMS method to assess corticospinal excitability J. Grandjean*, G. Derosiere, P. Vassiliadis, L. Quemener, Y. de Wilde, J. Duque, Université Catholique de Louvain, Belgium

[P2.135] Repetitive transcranial magnetic stimulation for the prevention of depressive relapse/recurrence: an assessor-blind, randomized controlled trial H-N. Wang*

1, X-X. Wang

1, R-G. Zhang

1, Y. Wang

1, M. Cai

1, Y-H. Zhang

1, R-Z. Sun

1, L. Guo

1, Y-T. Qiao

1, J-C. Liu

1,

H. He1, Z-H. Wang

1, Y-C. Wan

1, Q-R. Tan

1, Z-J. Zhang

1 ,2,

1The Fourth Military Medical University, China,

2The

University of Hong Kong, Hong Kong

[P2.136] The role of right inferior frontal gyrus in impulsivity: insights from high-frequency repetitive transcranial magnetic stimulation C-C. Yang*

1, N. Khalifa

1, B. Völlm

1, S. Lankappa

2,

1University of Nottingham, UK,

2Nottinghamshire

Healthcare NHS Trust, UK

[P2.137] Multifocal low-frequency rTMS contributes to a persistent therapeutic effect in essential tremor R. Lu, G. Dong, X. Chen, L. Wang, X. Zhou*, Changzhou No.2 People's Hospital, China

[P2.138] Effects of rTMS based on brain activation during language performance in stroke patients with non-fluent Aphasia (Pilot Study) B.S. Kwon*

2, N-J. Paik

1, W-S. Kim

1, J-H. Park

1, S. Kwon

1,

1Seoul National University Bundang Hospital,

Republic of Korea, 2

Dongguk University Ilsan Hospital, Republic of Korea

[P2.139] EEG functional connectivity predicts propagation of TMS-evoked potentials J.J.T. Vink*

1, M.B. Westover

3, A. Pascual-Leone

2, M.M. Shafi

2,

1University of Twente, The Netherlands,

2Beth

Israel Deaconess Medical Center, USA, 3

Massachusetts General Hospital, USA

[P2.140] Repetitive Transcranial Magnetic Stimulation (rTMS) can improve olfactory dysfunction in Parkinsonian syndrome: Case study A. Marei*, H. Rashed, Brains' Clinic Maadi, Egypt

[P2.141] Cathodal/Anodal technique use of repetitive transcrainal Magnetic stimulation in treatment of neuropsychiatry disorders A. Marei*, H. Rashed, Brains' Clinic Maadi, Egypt

[P2.142] Effectiveness and acceptability of intensive repetitive Transcranial magnetic stimulation (I-rTMS) in negative symptoms of Schizophrenia T. Sverak*

1 ,2, L. Albrechtova

1, L. Ustohal

1 ,2,

1Masaryk University and University Hospital Brno, Czech

Republic, 2

Central European Institute of Technology, Masaryk University, Czech Republic

[P2.143] Could Pinch force MVC be improved by training when coupled with pairs at 2.0ms of threshold TMS pulses? A. Maruyama*

1, K. Ono

1, D. Sato

1, Y. Yamashiro

1, A. Nuruki

2, Y. Nakamura

3, T. Touge

4, J. Rothwell

5,

1Niigata

University of Health and Welfare, Japan, 2

Kagoshima University, Japan, 3

Sakai Hospital, Kinki University, Japan,

4Kagawa University, Japan,

5Institute of Neurology UCL, UK

[P2.144] Pilot study of supplementary motor area rTMS for Tourette's syndrome in children C. Kahl*

1, A. Kirton

1, T. Pringsheim

1, P. Croarkin

2, Q. McLellan

1, R. Swansburg

1, E. Zewdie

1, F.P.

MacMaster1,

1University of Calgary, Canada,

2Mayo Clinic, USA

[P2.145] Effect of repetitive high frequency transcranial magnetic stimulation on trigeminal neuralgia J. Lopez-Trigo Mateu*

1, J. Lopez-Trigo Picho

2, J. Escudero

2, P. Ortiz

2,

1Univerisdad Cardenal Herrera CEU,

Spain, 2

Hospital General Universitario de Valencia, Spain

[P2.146] Open label trial of rTMS for treatment resistant depression in youth Q. McLellan, A. Kirton, C. Kahl*, Y. Jasaui, C. Wilkes, R. Swansburg, E. Zewdie, F.P. MacMaster, University of Calgary, Canada

[P2.147] Effects of low-frequency rTMS of the unaffected hemisphere in chronic stroke: a concomitant TMS and fMRI study A. Salatino*

1, R. Morese

1 ,2, M. Daniele

1, A. Berti

1, P. Perozzo

3, M.T. Molo

3, P. Cerrato

1, M. Nobili

4, C.

Valentini5, R. Ricci

1,

1University of Turin, Italy,

2Università della Svizzera Italiana, Switzerland,

3Carlo Molo

Foundation onlus, Italy, 4

Koelliker Hospital, Italy, 5

Hospital-Città della Salute e della Scienza di Torino, Italy

[P2.148] Effectiveness of rTMS in depression: A brief report M. Pirmoradi*, F. Asadi, Iran University of Medical Science, Iran

[P2.149] Development of low-intensity focused ultrasound (LIFU) based MRI-compatible brain stimulation system H. Cho

1, K. Pahk

2, H. Kim*

2,

1Korea University, Republic of Korea,

2Korea Institute of Science and Technology,

Republic of Korea


[P2.150] Transcranial ultrasound improves mood and affects resting state functional connectivity in healthy volunteers J.L. Sanguinetti*

1 ,2, J.J.B. Allen

1,

1University of New Mexico, USA,

2Army Research Laboratory, USA,

3University of Arrizona, USA

[P2.151] Sensing ultrasound promotes axon growth during development Z. Qiu*, L. Song, J. Wang, S. Kala, L. Sun, The Hong Kong Polytechnic University, Hong Kong

[P2.152] Multi-position brain stimulation on mouse by array ultrasound G. Li, Q. Jiang, J. Hong, P. Mu, G. Yang, C. Wang, W. Qiu*, H. Zheng, Shenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, China

[P2.153] Transcutaneous vagus nerve stimulation for patients with treatment-resistant depression B. Verkuil*

1, A.M. van Hemert

2, E.J. Giltay

2, R.M. Kok

3, E. Verwijk

3, H.P. Spaans

3, A.J.W. Does

1,

1University of

Leiden, The Netherlands, 2

Leiden University Medical Hospital, The Netherlands, 3

Parnassia Psychiatric Institute, The Netherlands

[P2.154] Transcutaneous vagal nerve stimulation to promote the extinction of fear B. Verkuil

1, A.M. Burger*

1, I. van Diest

2, B. Vervliet

3, W. van der Does

1, J.F. Thayer

4, J.F. Brosschot

1,

1Leiden

University, The Netherlands, 2

KU Leuven, Belgium, 3

Harvard Medical School, USA, 4

The Ohio State University, USA

[P2.155] Obesity-associated alterations in glucose metabolism are reversed by chronic bilateral stimulation of the abdominal vagus nerve C.H. Malbert*

1, C. Picq

2, J-L. Divoux

2, C. Henry

3, M. Horowitz

4,

1AniScan INRA, France,

2Axonic, France,

3LivaNova, France,

4University of Adelaide, Australia

[P2.156] Transcutaneous vagal nerve stimulation (tVNS) improves reversal of chronic autonomic dysfunction when added to a multi-faceted anti-inflammatory regimen P. Nemechek*

1, J. Nemechek

1, J. Colombo

2,

1Nemechek Consultative Medicine, Inc, USA,

2ANSAR Medical

Technologies, Inc., USA

[P2.157] Transcutaneous vagus nerve stimulation (tVNS) reverses autonomic dysfunction and symptoms associated with chronic traumatic encephalopathy (CTE) P. Nemechek*, J. Nemechek, Nemechek Consultative Medicine, Inc., USA

[P2.158] Transcutaneous vagus nerve stimulation (tVNS), rifaximin, extra virgin olive oil and DHA reverse autonomic dysfunction in an athlete with postconcussion syndrome P. Nemechek*, J. Nemechek, Nemechek Consultative Medicine, Inc., USA

[P2.159] Immediate effects of vagus nerve stimulation on human cognition and emotion K. Holm*

1 ,2, L. Sun

1 ,2, J. Peräkylä

1 ,2, J. Haapasalo

1, K. Lehtimäki

1, K.H. Ogawa

3, J. Peltola

1 ,2, K.M. Hartikainen

1

,2,

1Tampere University Hospital, Finland,

2University of Tampere, Finland,

3Saint Mary's College of California,

USA

[P2.160] tDCS effects in attention-deficit/hyperactivity disorder as shown by functional cortical networks: a randomized, double-blind, sham-controlled trial C. Cosmo*

1 ,2, C. Ferreira

1, J.G.V. Miranda

1, R.S. Rosario

1, A. Baptista

1, P. Montoya

1 ,3, E.P. Sena

1,

1Federal

University of Bahia, Brazil, 2


University of the Balearic Islands, Spain

[P2.161] Does tDCS modulate inhibitory control in ADHD? C. Cosmo*

1 ,2, A. Baptista

1, A.N. Araújo

1, R.S. Rosario

1, J.G.V. Miranda

1, P. Montoya

1 ,3, E.P. Sena

1,

1Federal



University of the Balearic Islands, Spain

[P2.162] Transcranial ultrasound (TUS) reduces worry in a five-day double-blind pilot study S.J. Reznik

1, J.L. Sanguinetti

1 ,2, J.J.B. Allen*

1,

1University of Arizona, USA,

2University of New Mexico, Army

Research Laboratory, USA

[P2.163] Preoperative stratification of gait outcome from subthalamic nucleus stimulation I. Hanci*, M. Scholten, L.P. Roncoroni, A. Gharabaghi, D. Weiss, University of Tuebingen, Germany

[P2.164] State-dependent modulation of brain-to-spinal cord connectome A.K. Yeung

1, H. Zhong

1, R.R. Roy

1, V.R. Edgerton

1, G. Garcia-Alias*

1,

1University of California,Los Angeles,

USA, 2

Universitat Autònoma de Barcelona, Spain


Poster Sessions 3 Wednesday, 8th March 2017 at 12:00-13:30

[P3.001] Electrophysiologic signatures of SCC-DBS efficacy V.R. Tiruvadi*, A. Veerakumar, A. Crowell, A. Waters, R. Butera, P. Riva-Posse, H. Mayberg, Emory University, USA

[P3.002] Optimization of deep brain stimulation in STN among patients with Parkinson's disease using a novel EEG-based tool D. Sand*

1, Z. Peremen

1 ,3, D. Haor

1 ,2, D. Arkadir

4, H. Bergman

5, A. Geva

1 ,2,

1ElMindA Ltd, Israel,

2Ben Gurion

University, Israel, 3

Tel Aviv University, Israel, 4

Hadassah-Hebrew University Medical Center, Israel, 5

Hebrew University, Israel

[P3.003] Differentiated effects of DBS and dopaminergic medication on somatosensory processing in PD K.S. Sridharan*

1 ,2, A. Højlund

1 ,2, E.J. Johnsen

1, N.A. Sunde

1, S. Beniczky

1 ,3, K. Østergaard

1,

1Aarhus

University Hospital, Denmark, 2

Center of Functionally Integrative Neuroscience, Denmark, 3

Danish Epilepsy Center, Denmark

[P3.004] Deep brain stimulation of human nucleus accumbens modulates parieto-frontal activity and induces behavioural changes related to sustained attention and executive control J.J. Gonzalez-Rosa*

1, B. Reneses

2, N. Parashkev

3, F. Lopez-Sosa

1, M. Yebra

1, J. Garcia-Albea

2, A. Oliviero

4, J.A.

Barcia2, B.A. Strange

1 ,5,

1Technical University of Madrid, Spain,

2Hospital Clínico San Carlos - Instituto de

Investigación Sanitaria San Carlos (IdISSC), Spain, 3

Institute of Neurology - UCL, UK, 4

Hospital Nacional de Parapléjicos, Spain,

5Alzheimer’s Disease Research Centre & Reina Sofia-CIEN Foundation, Spain

[P3.005] Deep brain stimulation for treatment resistant depression: challenges in recruitment K. Williams, S. Golding, A. Mackie, G. MacQueen, Z. Kiss, R. Ramasubbu*, University of Calgary, Canada

[P3.007] Analysis of cortical connectivity based on time-frequency transfer entropy during unimanual movement P. Xie*, Y.Y. Zhang, M.S. Qi, S. Zhou, X.G. Wu, Yanshan University, China

[P3.008] Auditory steady state response in schizophrenia, bipolar disorder, and healthy controls S.K. Kim*

1 ,2, S.K. Jang

1, D.W. Kim

3, C.H. Im

2, S.H. Lee

1 ,4,

1Clinical Emotion and Cognition Research

Laboratory, Republic of Korea, 2

Hanyang University, Republic of Korea, 3

Chonnam National University, Republic of Korea,

4Inje University Ilsan Paik Hospital, Republic of Korea

[P3.009] The relationship between the individual alpha frequency (IAF) and response to synchronized transcranial magnetic stimulation (sTMS) for treatment of major depressive disorder (MDD) A.F. Leuchter*

1, J. Bissett

2, P. Manberg

3, L. Carpenter

4 ,7, J.M. Massaro

5, M. George

6,

1University of California

Los Angeles, USA, 2

Neosync Inc., USA, 3

Corolla Clin/Reg Consulting, USA, 4

Brown University, USA, 5

Boston University, USA,

6Medical University of South Carolina, USA,

7Butler Hospital, USA

[P3.010] Combining transcranial magnetic stimulation and electroencephalography to investigate the neural correlates of giving-up on problem solving E. Miyauchi*

1, M. Kawasaki

1,

1University of Tsukuba, Japan,

2RIKEN Brain Science Institute, Japan

[P3.011] Frontal and temporal cortical functional recovery after electroconvulsive therapy for depression: A longitudinal functional near-infrared spectroscopy study J. Hirano*

1, A. Takamiya

1, B. Yamagata

1, S. Hotta

1, Y. Miyasaka

1, S. Pu

3, A. Iwanami

2, H. Uchida

1, M.

Mimura1,

1Keio University School of Medicine, Japan,

2Showa University School of Medicine, Japan,

3Tottori

University Faculty of Medicine, Japan

[P3.012] ECT-related anxiety: what have we (not) learned? J. Obbels

1, E. Verwijk

1, F. Bouckaert

1, P. Sienaert*

1,

1University of Leuven, Belgium,

2Parnassia Psychiatric

Institute, The Netherlands, 3

University Psychiatric Center KU Leuven, Belgium

[P3.013] Electroconvulsive therapy for behavioural problems in dementia - a systematic review J.F. van den Berg, H.C. Kruithof, R.M. Kok, E. Verwijk*, H.P. Spaans, Parnassia Psychiatric Institute, The Netherlands

[P3.014] A Proof of concept clinical trial of feasibility course of low Amplitude Seizure Therapy (LAP-ST) in man: Less cognitive side effects with retention of efficacy N.A. Youssef*

1, E. Sidhom

2 ,3,

1Augusta University, USA,

2The Behman Hospital, Egypt,

3Oxford Health NHS

Foundation Trust, UK

[P3.015] Electroconvulsive therapy modulates intralimbic and corticolimbic information flow: partial Granger causality analysis of resting EEG A. Takamiya*

1 ,2, J. Hirano

1, R.D. Pascual-Marqui

3 ,4, S. Kito

5, T. Kishimoto

1, M. Mimura

1,

1Keio Univrsity


School of Medicine, Japan, 2

Komagino Hospital, Japan, 3

University Hospital of Psychiatry, Switzerland,

4Kansai Medical University, Japan,

5National Center of Neurology and Psychiatry, Japan

[P3.016] Reduced serum lipid levels in patients receiving ECT - preliminary findings A. Stautland

1, U. Kessler*

2, L. Oltedal

1 ,2, J. Haavik

2 ,3, K.J. Oedegaard

1 ,2,

1University of Bergen, Norway,

2Haukeland University Hospital, Norway,

3K.G. Jebsen Centre for Neuropsychiatric Disorders, Norway

[P3.017] Use of unilateral electroconvulsive therapy to treat ultra-refractory schizophrenia G. Cotovio

1 ,2, A. Velosa

1 ,2, A. Oliveira-Maia

1 ,2, B. Bernardo Barahona-Correa*

1,

1Centro Hospitalar de Lisboa

Ocidental and NOVA Medical School, Portugal, 2

Champalimaud Centre for the Unknown, Champalimaud Clinical Centre and Neuroscience Programme, Portugal

[P3.023] Seizure threshold increases are predicted by EEG quality in right Unilateral Ultrabrief ECT V. Galvez*

1 ,2, S. Waite

3, D. Hadzi-Pavlovic

1 ,2, C.K. Loo

1 ,2,

1University of New South Wales, Australia,

2Black

Dog Institute, Australia, 3

Queen Elisabeth Hospital, Australia

[P3.024] ECT Modality and health related quality of life outcomes after ECT for depression V. Galvez*

1 ,2, A. Li

1 ,2, C. Oxley

1, S. Waite

4, N. de Felice

5, D. Hazdi-Pavlovic

1 ,2, D. Kumar

1 ,2, A. Page

5 ,6, G.

Hooke5, C.K. Loo

1 ,2,

1University of New South Wales, Australia,

2The Black Dog Institute, Australia,

3IOP, UK,

4The Queen Elizabeth Hospital, Australia,

5Perth Clinic, Australia,

6The University of Western Australia,

Australia, 7

St George Hospital, Australia

[P3.025] Clinical benefits of electroconvulsive therapy for depressed patients with refractory complex regional pain syndrome (CRPS) type 1: A preliminary result T.S. Kim*, H.J. Park, Y.H. Kim, D.E. Moon, The Catholic University of Korea, Republic of Korea

[P3.027] How long should ECT course in adolescents last? A retrospective review H. Maoz*

1 ,2, U. Nitzan

1 ,2, Y. Goldwin

2, I. Krieger

1 ,2, Y. Bloch

1 ,2,

1Tel Aviv university, Israel,

2Shalvata Mental

Health Center, Israel

[P3.028] Bridging to deep brain stimulation implantation using electroconvulsive therapy in Parkinson’s disease N.R. Williams

1, G. Sahlem

2, J. Pannu*

1, I. Takacs

2, B. Short

2, G. Revuelta

2, M. George

2,

1Stanford University,

USA, 2

Medical University of South Carolina, USA

[P3.029] Risk of pulmonary aspiration with the outpatient electroconvulsive therapy: Case report M. Gad*

1 ,2, A. Elaghoury

1,

1Saudi-German Hospital, Saudi Arabia,

2Abbassia Mental Hospital, Egypt

[P3.030] Medical morbidity and mortality after electroconvulsive therapy in a population-based sample Medical morbidity and mortality after electroconvulsive therapy in a population-based sample D.M. Blumberger*

1, D.P. Seitz

2 ,3, N. Herrmann

3, J.G. Kirkham

2, C. Reimer

2, P. Kurdyak

1 ,3, M.J. Rapoport

1, Z.J.

Daskalakis1, B.H. Mulsant

1, S.N. Vigod

1,


2Queen's University, Canada,

3Institute for Clinical Evaluative Sciences, Canada

[P3.032] Change management in psychiatry: Reintroducing ECT after more than four decades of neglect J.C. Müller*, D. Lüdecke, H. Albrecht, A.D. Scholz-Hehn, J. Schulze-Thüsing, L. Stumm, N. Freundlieb, University Medical Center Hamburg-Eppendorf, Germany

[P3.033] Ketamine infusions after failure to respond to electroconvulsive therapy: a case series report P. Riva-Posse*, G. Galendez Snead, W.M. McDonald, Emory University School of Medicine, USA

[P3.034] Clinical response to electroconvulsive therapy among patients with treatment-refractory psychosis: the BC Psychosis Program experience N.J. Ainsworth*

1 ,2, A. Leon

2, K. Green

2, R.F. White

1 ,3, J. Sung

2, G. Smith

1 ,3, R. Shalbaf

2, A. Singh

2, W.G.

Honer1, F. Vila-Rodriguez

1 ,2,


2Non-invasive Neurostimulation

Therapies Laboratory, Canada, 3

British Columbia Psychosis Program, Canada

[P3.035] Electroconvulsive therapy in chronic psychotic patients: the interface between perceived stress, anxiety and depression and clinical outcome D. Mabunda*

1 ,2, A. Palha

4, J. Mari

5, M. Morais

1, A. Pala

3, J. Mota

6, M. Oquendo

3, J. Bessa

1,

1University of

Minho, Portugal, 2

University Eduardo Mondlane, Mozambique, 3

Columbia University, USA, 4

University of Porto, Portugal,

5University Federal of São Paulo, Brazil,

6Hospital Magalhães Lemos, Portugal

[P3.036] Left unilateral ultrabrief ECT in a patient with Cerebral Aneurysms and right side stoke A.Z. Elmaadawi*, S. Mashaly, S. Nasr, Beacon Health System, USA

[P3.037] EEG responses to direct electrical stimulation and correlations to post-stimulus parameters in electroconvulsive therapy (ECT). R.G. Ekedahl, NeuFydi, Sweden


[P3.038] Mood-enhancing effects of low field magnetic stimulation in depression and related plasticity of resting state connectivity M.J. Dubin*, A.A. Cochran, C.G. Gross, J.P. Dyke, H.U. Voss, B.D. Brody, P.J. Christos, J.H. Kocsis, C. Liston, Weill Cornell Medical College, USA

[P3.039] Low-field synchronized transcranial magnetic stimulation (sTMS) for treatment of depression: results from an open-label extension study M.T. Bhati*

1, M.E. Thase

2, J.L. Bissett

3, J.M. Massaro

4, A.F. Leuchter

5,

1Stanford University, USA,

2University

of Pennsylvania, USA, 3

NeoSync, USA, 4

Boston University, USA, 5

University of California Los Angeles, USA

[P3.040] Human acute neurophysiological responses to magnetically-induced alternating current densities of up to 100 mA.m

-2

A. Legros*1 ,2

, J. Modolo3 ,1

, M. Corbacio1, S. Davarpanah Jazi

1, S. Villard

1, D. Goulet

4, M. Plante

4, M.

Souques5, F. Deschamps

6, G. Ostiguy

4, C.M. Baker

1, J. Lambrozo

5, A.W. Thomas

1,

1LHRI and Western

University, Canada, 2

EuroMov, Université de Montpellier, France, 3

INSERM, France, 4

Hydro-Québec, Canada,

5EDF, France,

6RTE, France

[P3.041] Template instead of individual MRI in navigated TMS – a valid alternative in healthy subjects R. Fleischmann*, R. Bathe-Peters, A. Köhn, S. Schmidt, S. Brandt, Charité - Universitätsmedizin Berlin, Germany

[P3.042] GABAAergic and glutamatergic functions as measured by paired TMS paradigms combined with EEG from the dorsolateral prefrontal cortex in patients with schizophrenia Y.N. Noda*

1, M.S.B. Barr

1, R.Z. Zomorrodi

1, R.F.H.C. Cash

2, F.F. Farzan

1, R.C. Chen

1, Z.J.D. Daskalakis

1, D.M.B.

Blumberger1,


2Monash University Central Clinical School and The Alfred,

Australia

[P3.043] Brainstem activity changes following repetetive transcranial magnetic stimulation in spinal cord injury subjects H. Kumru*

1, J. Valls-Sole

2, S. Albu

1, J. Vidal

1,

1Institut Guttman, Spain,

2Hospital Clinic, Spain

[P3.044] Changes in the level of voluntary activation after fatiguing finger tapping A. Madrid*, E. Medinabeitia, J. Cudeiro, P. Arias, Universidade da Coruña, Spain

[P3.045] Estimation of interindividual characteristics of pre- and post-synaptic GABA-mediated inhibitory mechanisms in healthy individuals using SICI, LICI and LICF tests A.V. Masliukova

1, N.A. Smirnov*

1 ,2,

1Ivanovo State Medical Academy, Russia,

2Neurosoft, Russia

[P3.046] Probing parietal-motor connectivity by means of intraoperative direct cortical stimulation L. Cattaneo*, P. Meneghelli, V. Tramontano, F. Sala, University of Verona, Italy

[P3.048] Consecutive anodal transcranial direct current stimulation enhances synaptic plasticity, dendritic morphology and working memory in a diabetic rat model Y.J. Wu*, C.C. Lin, K.S. Hsu, National Cheng Kung University, Taiwan

[P3.049] Effects of transcranial static magnetic stimulation (tSMS) of M1 on afferent inhibition in humans P. Arias*, L. Arcay, B. Puerta, J. Cudeiro, Universidade da Coruña, Spain

[P3.050] Impact of galvanic vestibular stimulation on mood F. Pasquier

1 ,2, C. Guillot

1 ,2, P. Denise

1 ,2, G. Quarck*

1 ,2,

1University of Caen Normandy, France,

2Lab INSERM

Comete U1075, France

[P3.051] Impairment of median nerve somatosensory evoked potentials in schizophrenia A.A. Daskalakis*

1, R. Zomorrodi

1 ,2, L. Tran

1 ,2, A. Ziluk


1 ,2, T.K. Rajji

2,

1Centre for

Addiction and Mental Health, Canada, 2


[P3.052] The acute effects of a combined yoga and transcranial direct current stimulation on neurophysiological markers: preliminary data M. Danilewitz*, C. Pang, D. Aur, R. Shalbaf, R. Ge, J. Brown, E. McLellan, F. Vila-Rodriguez, University of British Columbia, Canada

[P3.053] Influence of the BDNF Val66Met polymorphism on the balance of excitatory and inhibitory neurotransmission and relationship to plasticity in human cortex R. Cash*

1 ,3, K. Udupa

1, C. Gunraj

1, F. Mazzella

1, Z.J. Daskalakis

2, A.H. Wong

2, J.L. Kennedy

2, P.B. Fitzgerald

3,

R. Chen1,

1Toronto Western Research Institute, Canada,

2Centre for Addiction and Mental Health, Canada,

3Monash Alfred Psychiatry Research Centre, Australia

[P3.054] Effect of transcranial pink noise stimulation of anterior cingulate cortex on food craving S.L. Leong*

1, D. de Ridder

1, S. Vanneste

2, S. Ross

1, W. Sutherland

1, P. Manning

1,

1University of Otago, New

Zealand, 2

University of Texas at Dallas, USA


[P3.055] A clinical study on the low frequency stimulation to improve the freezing of gait for patients of Parkinson’s disease after deep brain stimulation. W. Lin*

1, J.J. Wu

2, L.K. Yang

1,

1No 101 Hospital of Chinese PLA, China,

2Huashan Hospita, China

[P3.056] Localized currents generated by simultaneous ultrasound and oscillating magnetic fields Y. Li*, L. Hernandez-Garcia, T. Hall, C. Cain, University of Michigan, USA

[P3.057] Transcranial static magnetic field stimulation over the primary motor cortex decreases cortical nociceptive processing H. Kirimoto*, H. Tamaki, N. Otsuru, K. Yamashiro, H. Onishi, Niigata University of Health and Welfare, Japan

[P3.058] Effects of transcranial static magnetic field stimulation (tSMS) of the visual cortex on experimental photophobia V. Soto-León*

1, E. Lozano-Soto

1, S. Sabbarese

1, B.A. Strange

2, G. Foffani

1, A. Oliviero

1,

1Hospital Nacional de

Parapléjicos, Spain, 2

Universidad Politecnica de Madrid, Spain

[P3.059] Acoustic mechanogenetics: A promising tool for probing brain function Z. Qiu*

1, Y. Yang

1, J. Guo

2, S. Kala

1, L. Yang

1, H.C. Chan

2, L. Sun

1,

1The Hong Kong Polytechnic University,

Hong Kong, 2

The Chinese University of Hong Kong, Hong Kong

[P3.060] On certain possibilities of the neck neural structures neuro-electrostimulation method V.S. Kublanov

1, K.Y. Retyunskiy

2, T.S. Petrenko

1 ,2, A.A. Petrenko*

1,

1Ural Federal University, Russia,

2Ural

State Medical University, Russia

[P3.062] Dynamic neural state identification in deep brain local fields potentials by wavelet packet transform H. Luo*

1 ,2, X. Du

1 ,2, Y. Huang

1, A. Green

3 ,4, A. Aziz

3 ,4, S. Wang

1,

1Chinese Academy of Sciences, China,

2University of Chinese Academy of Sciences, China,

3University of Oxford, UK,

4John Radcliffe Hospital, UK

[P3.063] Real-time source-level EEG network activity state triggered TMS with millisecond resolution P. Belardinelli*, D. Desideri, C. Zrenner, U. Ziemann, University Hospital of Tuebingen, Germany

[P3.064] Transcranial static magnetic field stimulation modulates motor cortex excitability in off medication PD patients M. Dileone*

1, L. Mordillo-Mateos

2, M.C. Carrasco-Lopez

2, J.C. Segundo-Rodriguez

3, N. Lopez-Aristegui

3, F.

Alonso-Frech4, M.J. Catalan-Alonso

4, J.A. Obeso

1, A. Oliviero

2, G. Foffani

1,

1HM Hospital Puerta del Sur,

Spain, 2

Hospital Nacional de Parapléjicos, Spain, 3

Hospital Virgen de la Salud, Spain, 4

Hospital Clinico San Carlos, Spain

[P3.065] Long-lasting effects of transcranial static magnetic field stimulation on motor cortex excitability L. Mordillo-Mateos*

1, M. Dileone

2, A. Oliviero

1, G. Foffani

2,

1Hospital Nacional de Parapléjicos, Spain,

2HM

Hospital Puerta del Sur, Spain

[P3.066] High-resolution electrophysiologic recording during deep brain stimulation surgery using a custom hybrid electrode A.L. Hewitt*, S.M. Stead, B.T. Klassen, Mayo Clinic, USA

[P3.067] Magnetic seizure therapy compared to ECT in major depressive disorder: A medication-free clinical controlled trial F.A. El-Deeb

1, E.A. Gad

1, A.A. Kandeel

2, A.A. Haiba

1, S.M. Sadek

1, N.A. Youssef*

3,

1Tanta University, Egypt,

2Cairo University, Egypt,

3Medical College of Georgia at Augusta University, USA

[P3.068] Brain self-regulation in criminal psychopaths L.K. Konicar*

1 ,2, N.B. Birbaumer

2, L.P. Poustka

1,

1Medical University of Vienna, Austria,

2Eberhard-Karls-

University, Germany

[P3.069] Using EVestG for quantitative measurement of rTMS efficacy B. Lithgow*

1 ,2, Z. Moussavi

1, A. Sulieman

1, M. Modirrousta

1,

1University of Manitoba, Canada,

2Monash

Alfred Psychiatry Research Center, Australia

[P3.070] Auricular acupuncture vs. progressive muscle relaxation and no intervention for exam anxiety in medical students – A randomized controlled trial with non-randomized condition G. Schultz*

1, C. Altenstein

1, C. Klausenitz

1, T. Hesse

1, H. Hacker

1, A. Petersmann

1, H.J. Hannich

1, K.

Hahnenkamp1, T. Usichenko

1 ,2,

1University Medicine of Greifswald, Germany,

2McMaster University, Canada

[P3.071] The characteristics of the phosphenes elicited by Artificial Vision by Direct Optic Nerve Electrical stimulation (AV-DONE). K. Nishida*

7, H. Sakaguchi

2, M. Kamei

3, C. Gonzalez

4, Y. Terasawa

5, T. Fujikado

2, R. Fontan

1, M. Ozawa

5, H.

Mercado6, K. Nishida

2,

1Asociacion Para Evitar la Ceguera, Mexico,

2Osaka University Graduate School of

Medicine, Japan, 3

Aichi Medical University, Japan, 4

Instituto Mexicano del Seguro Social, Mexico, 5

Nidek Co., Ltd., Japan,

6Denver Health Medical Center, USA,

7Kansai Medical University, Japan


[P3.072] Using seizure adequacy measures to inform clinical decisions in magnetic seizure therapy F.A. Backhouse*

1 ,2, Y. Noda

1 ,2, J. Downar



1 ,2,

1University of Toronto,

Canada, 2

Centre for Addiction and Mental Health, Canada, 3

Toronto Western Hospital, Canada

[P3.073] Effects of cranial electric stimulation on the executive functions of patients with insomnia M.F. Pérez Pichardo*, C.A. Freyre Vega, J.A. Moo Estrella, Autonomus University of Yucatán, Mexico

[P3.074] In vitro platform for acoustic and electrophysiological investigations of ultrasound stimulation C. Thielemann*

1, M. Kupnik

2,

1University of Applied Sciences Aschaffenburg, Germany,

2Technische

Universität Darmstadt, Germany

[P3.075] Transcranial alternating current stimulation for boosting corticospinal excitability and restitution of intracortical inhibition in elderly M. Christova*

1 ,2, S. Fresnoza

3, E. Gallasch

1, A. Ischebeck

3,

1Medical University of Graz, Austria,

2University of

Applied Sciences Graz, Austria, 3

University of Graz, Austria

[P3.076] The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol C.V. Ide*, T. Thompson, University of Greenwich, UK

[P3.077] tDCS can alleviate the effects of poor sleep on cognition A. Sterr*, J. Ebajemito, University of Surrey, UK

[P3.078] Influence of cortical electrical stimulation on neural plasticity in a rat model of traumatic brain injury C.W. Peng*

1 ,3, S.C. Chen

2 ,3, T.H. Hsieh

4,

1Taipei Medical University, Taiwan,

2DepartmenChang Gung

University, Taiwan

[P3.079] High frequency repetitive somatosensory stimulation increases sensori-motor inhibition and leads to perceptual improvement in healthy subjects L.R. Rocchi*

1 ,2, R.E. Erro

1 ,3, E.A. Antelmi

1 ,4, A.B. Berardelli

2 ,5, M.T. Tinazzi

3, R.L. Liguori

4 ,6, K.B. Bhatia

1, J.C.R.

Rothwell1,


2University of Rome Sapienza, Italy,

3University of Verona, Italy,

4University of Bologna, Italy,

5IRCCS Neuromed Institute, Italy,

6IRCSS Institute of Neurological Sciences, Italy

[P3.080] Cathodal trans-spinal direct current stimulation (tsDCS) is harmful in ALS patients: direct evidence from intradiaphragmatic recordings M-C. Nierat*

1 ,2, I. Rivals

1 ,6, J. Gonzalez-Bermejo

1 ,4, C. Morelot-Panzini

1 ,4, T. Similowski

1 ,4, J-C. LAMY

3

,5,

1INSERM, UMRS1158, France,

2Sorbonne Universités, UPMC Univ Paris 06, France,

3Inserm U 1127, France,

4AP-HP, Groupe Hospitalier Pitié-Salpêtrière Charles Foix, France,

5Institut du Cerveau et de la Moelle

épinière, France, 6

ESPCI ParisTech, France

[P3.081] Altered neuroplasticity of prefrontal cortex in adult autism spectrum disorder M. Nakamura*

1 ,2, T. Itahashi

1, T. Izuno

2, J. Fujino

1, H. Ohta

1, R. Hashimoto

1, N. Kato

1,

1Showa University,

Japan, 2

Kanagawa Psychiatric Center, Japan

[P3.082] Functional network reorganization by dual-mode noninvasive brain stimulation in stroke patients J. Lee*

1, E. Park

2, A. Lee

3, W.H. Chang

2, D.S. Kim

1, Y.H. Kim

2 ,3,

1Korea Advanced Institute of Science and

Technology, Republic of Korea, 2

Sungkyunkwan University School of Medicine, Republic of Korea,

3Sungkyunkwan University, Republic of Korea

[P3.083] Heavy cannabis smoking linked to impaired cortical plasticity in young adults J.F. Martin-Rodriguez*

1, M. Ruiz-Veguilla

2, P.A. de Toledo

1, A. Usobiaga

3, M. Canal-Rivero

2, J. Garcia-Egea

2, L.

Vargas1, A. Rodriguez-Baena

1, N. Etxebarria

3, P. Mir

1,

1Universidad de Sevilla, Spain,

2UGC Salud Mental HVR,

Spain, 3

University of the Basque Country (UPV/EHU), Spain

[P3.084] Neuroplasticity changes after rTMS in patient with secondary-progressive multiple sclerosis and severe spacticity J. Korzhova, A. Chervyakov, I. Bakulin, M. Zakharova, A. Poydasheva*, N. Suponeva, L. Chernikova, R. Konovalov, I. Zavalishin, M. Piradov, Russian Research Center of Neurology, Russia

[P3.085] Quadri-pulse theta burst stimulation using ultra-high frequency bursts at I-wave periodicity induces direction dependent bi-directional plasticity in human motor cortex N. Jung

1, B. Gleich*

2, N. Gattinger

2, C. Hoess

1, C. Haug

1, H.R. Siebner

3, V. Mall

1,

1Technische Universität

München, Germany, 2

Danish Research Center for Magnetic Resonance (DRCMR), Denmark

[P3.086] Diffusion tensor imaging evaluation of neural network development in patients undergoing therapeutic repetitive transcranial magnetic stimulation following stroke N. Yamada*

1, R. Ueda

3, W. Kakuda

1, R. Momosaki

1, T. Kondo

2, T. Hara

1, A. Senoo

3, M. Abo

1,

1The Jikei

University School of Medicine, Japan, 2

Shimizu Hospital, Japan, 3

Tokyo Metropolitan University, Japan


[P3.087] Reduced neuroplasticity in the dorsolateral prefrontal cortex in patients with depression as indexed by paired associative stimulation paradigm combined with EEG Y.N. Noda*

1, R.Z. Zomorrodi

1, Z.J.D. Daskalakis

1, F.V.R. Vila-Rodriguez

1 ,2, J.D. Downar

1, F.F. Farzan

1, T.K.R.

Rajji1, D.M.B. Blumberger

1,


2University of British Columbia, Canada

[P3.088] Effect of iTBS on cortical and corticospinal excitability in healthy subjects: a TMS-EEG-EMG study T. Gedankien, M.M. Shafi*, P.J. Fried, A. Pascual-Leone, Beth Israel Deaconess Medical Center, USA

[P3.089] APOE polymorphism and cortical plasticity are independently associated with cognitive decline in Alzheimer's disease F. Di Lorenzo*

1 ,2, C. Motta

1 ,2, V. Ponzo

1, A. Martorana

1 ,2, C. Caltagirone

1 ,2, G. Koch

1 ,2,

1IRCCS Fondazione

Santa Lucia, Italy, 2

Tor Vergata University, Italy

[P3.090] Face-hand interactions revealed by SAI J. Moly

1 ,2, B. Ramalho*

3, A. Farnè

1 ,4, K.T. Reilly

1 ,2,

1Lyon Neuroscience Research Center, France,

2Lyon 1

University, France, 3

Federal University of Rio de Janeiro, Brazil, 4

Hospices Civils de Lyon, Neuro-immersion & Mouvement et Handicap, France

[P3.091] Improving lower limb strength in incomplete spinal cord injury with non-invasive spinal associative stimulation M. Cortes*

1 ,2, G. Thickbroom

3, J. Valls-Sole

2, P. Shirvalkar

1, A. Pascual-Leone

4, D. Edwards

1 ,3,

1Cornell

University, USA, 2

Barcelona University, Spain, 3

University of Western Australia, Australia, 4

Harvard medical school, USA

[P3.092] Predictors of clinical response to deep transcranial magnetic stimulation (dtms) in unipolar major depression: a systematic review and meta-analysis K.K. Kedzior*

1, C. Müller

1, I. Gerkensmeier

1, H.M. Gellersen

2, M. Schuchinsky

3,

1University of Bremen,

Germany, 2

Maastricht University, The Netherlands, 3

University of Limerick, Ireland

[P3.093] Improving the strength and focality of transcranial alternating current stimulation for clinical applications: A modelling study exploring the benefits of a subcutaneous electrode A. Khatoun*, M. Mc Lauglin, KU Leuven, Belgium

[P3.094] The effects of offline frontal δ-tACS on evoked endogenous oscillatory activity M. Wischnewski*, D.J.L.G. Schutter, Donders Institute, The Netherlands

[P3.095] Facilitating word memorizing: frequency specificity of transcranial alternating current stimulation (tACS)? S. Weiss*

1 ,2, H.M. Müller

1,

1Bielefeld University, Germany,

2CITEC, Bielefeld University, Germany

[P3.096] Going beyond the Eureka moment: enhancement of insightful solutions by means of tACS and tRNS G. Sprugnoli*

1, S.L. Liew

2, E. Bricolo

3 ,4, G. Costantini

3, C. Salvi

5, C.S. Musaeus

6, S. Rossi

1, A. Rossi

1, A. Pascual-

Leone1, E. Santarnecchi

1 ,7,

1Siena Medical School, Italy,

2University of Southern California, USA,

3University of

Milano-Bicocca, Italy, 4

Milan Center for Neuroscience, Italy, 5

Northwestern University, USA, 6

University of Copenhagen, Denmark,

7Harvard Medical School, USA

[P3.097] Can transcranial alternating current stimulation simultaneously increases and decreases cortical excitability? Supporting evidence from the rat motor cortex M. Mc Laughlin*, A. Khatoun, KU Leuven, Belgium

[P3.098] Connectivity and interhemispheric inhibition between motor cortices: a study with transcranial alternating current stimulation L-P. Lafleur*

1 ,2, G. Klees-Themens

1, G. Lefebvre

1, J-F. Lepage

3, H. Théoret

1 ,2,

1Université de Montréal,

Canada, 2

Centre Hospitalier Universitaire Sainte-Justine, Canada, 3

Université de Sherbrooke, Canada

[P3.099] Frequency-specific after-effects of transcranial alternating current stimulation (tACS) on motor learning: Preliminary data of a simultaneous tACS-EEG-NIRS study A. Berger*, N.H. Pixa, M. Doppelmayr, Johannes Gutenberg Universität Mainz, Germany

[P3.100] Phase-synchronized tACS-induced oscillatory activity modulates cortico-cortical signaling efficacy K.D. Fehér*

1, Y. Morishima

1,

1University Hospital of Psychiatry, Switzerland,

2PRESTO, Japan

[P3.101] Improvement in auditory verbal memory induced by theta tACS to bilateral dorsal prefrontal cortex R.H. Hashimoto*, A.K. Karima, Tokyo Metropolitan University, Japan

[P3.102] Recovering ERPs during a tACS amplitude sweep: A method for determining individual stimulation intensities J. Dowsett*, P. Taylor, Ludwig-Maximilians-Universität, Germany

[P3.103] Transcranial alternating current stimulation in the beta frequency promotes motor inhibition I. Leunissen*

1, J.P. Coxon

2, S.P. Swinnen

1,

1KU Leuven, Belgium,

2Monash University, Australia


[P3.104] Influence of burst tACS on the neural oscillations and detection of change in visual task M. Castellano*

1, D. Ibanez-Soria

1, J. Acedo

1, E. Kroupi

1, X. Martinez

4, A. Soria-Frisch

1, S. Dunne

2, J. Valls-

Sole3, A. Verma

1 ,4, G. Ruffini

1,

1Starlab Barcelona SL, Spain,

2Hospital Clinic and IDIBAPS, Spain,

3Biogen Inc.,

USA, 4

Neuroelectrics Corp., USA

[P3.105] Modulation of interhemispheric connectivity by alternating current stimulation and its impact on transitions between bimanual movements of varying stability K-F. Heise*, T.S. Monteiro, V. Gijbels, I.H. Leunissen, D. Mantni, S.P. Swinnen, Motor Control Laboratory Movement Control and Neuroplasticity Research Group KU Leuven, Belgium

[P3.106] Frequency specific modulation of motor fatigue by beta- and gamma-tACS M. Roennefarth*, A. Jooss, L. Haberbosch, A. Koehn, R. Fleischmann, S.A. Brandt, S. Schmidt, Charite Universitaetsmedizin Berlin, Germany

[P3.107] The effect of transcranial alternating current stimulation (tACS) on inhibitory control and error monitoring in healthy adults S.E. Peter*, D. Mederer, N. Habboush, E. Lyzhko, M. Siniatchkin, V. Moliadze, Christian-Albrechts-University, Germany

[P3.108] Cathodal transcranial direct current stimulation could restore MPTP induced neurotoxicity in mice through autophagy modulation W. Jang, Gangneung Asan hospital, Republic of Korea

[P3.109] Anodal tDCS over the left dorsolateral prefrontal cortex reduce conflict effect F. Chen, J.B. Sun, S.J. Fu, P. Liu*, Xidian University, China

[P3.110] Executive attention enhancement under stress: A TDCS randomized controlled trial Y. Ankri*

1, O. Meiron

2, Y. Braw

1,

1Ariel University, Israel,

2Herzog Medical Center, Israel

[P3.111] Designing a Transcranial Direct Current Stimulation (tDCS) device and its clinical certification through a randomized double-blind controlled trial in depressive patients R.B. Ribeiro*

1, S.P. Penteado

1 ,2, Q. Cordeiro

1,

1Santa Casa of São Paulo Medical School, Brazil,

2University of

São Paulo Medical School, Brazil

[P3.112] A case of tDCS for personal neglect syndrome J.H. Chang*, T.W. Kim, J.A. Yoon, Pusan National University Hospital, Republic of Korea

[P3.113] Effects of transcranial direct current stimulation on Internet gaming addiction: a preliminary positron emission tomography study H.S. Jeong*, J.K. Oh, E.K. Choi, I-U. Song, Y-A. Chung, Incheon St. Mary's Hospital, The Catholic University of Korea, Republic of Korea

[P3.114] Transcranial direct current stimulation (tDCS) interferes with cognitive bias mitigation learning L.K. McIntire*

1, R.A. McKinley

2, J.M. Nelson

3, C. Goodyear

1,

1Infoscitex, Inc., USA,

2711th Human

Performance Wing, USA, 3

Consortium of Research Fellows, USA

[P3.115] Safety and tolerability of transcranial direct current stimulation in Saudi population. M. Alohali*, A. Alhussien, F. Alghamdi, A. Alatawi, T. Almusned, S. Bashir, King Saud University, Saudi Arabia

[P3.116] Inter-individual variability in motor Cortex excitability assessment induced by Transcranial direct current stimulation in humans S. Bashir*

1, W. Kyoung Yoo

2, S. Ahmad

1, M. Alatefi

1, A. Abu Juma

1,

1King Saud University, Saudi Arabia,

2Hallym University, Republic of Korea

[P3.117] Tempering proactive cognitive control by means of tDCS of the lateral prefrontal cortex C.J. Gomez-Ariza*

1, M.C. Martín

1, J. Morales

2,

1Universidad de Jaén, Spain,

2Universidad Loyola Andalucía,

Spain

[P3.118] The effect of stimulation parameters in prefrontal tDCS research on cognition J. Dedoncker*

1, A. Brunoni

2, C. Baeken

1 ,3, M. Vanderhasselt

1 ,3,

1Ghent University, Belgium,

2University of

São Paulo, Brazil, 3

Free University of Brussels, Belgium

[P3.120] Repeated stimulation of the posterior parietal cortex in patients in minimally conscious state: a sham-controlled randomized clinical trial G. Martens*

1, A. Thibaut

2 ,1, W. Huang

3, H. Di

3, S. Laureys

1,

1University of Liège, Belgium,

2Harvard Medical

School, USA, 3

Hangzhou Normal University, China

[P3.121] The effects of transcranial direct current stimulation in chronic spinal cord injury: a quantitative EEG study M. Cortes

1 ,2, A. Climent

1, D. Putrino*

1, L. Dubreuil Vall

4, G. Ruffini

4, D. Labar

1, D.J. Edwards

1,

1Burke Medical

Research Institute, Weill Medical College of Cornell University, USA, 2

Universitat de Barcelona, Spain, 3

Starlab Barcelona SL, Spain


[P3.122] Encoding/retrieval dissociation of false recognition with transcranial direct current stimulation (tDCS) of the left temporal lobe E. Díez*

1, C.J. Gómez-Ariza

2, A.M. Díez-Álamo

1, M.A. Alonso

3, A. Fernandez

1,

1University of Salamanca -

INICO, Spain, 2

University of Jaen, Spain, 3

University of La Laguna - INICO, Spain

[P3.123] Transcranial direct current stimulation on cognitive deficits in schizophrenia Z. Narita*, T. Inagawa, K. Sueyoshi, T. Sumiyoshi, National Center of Neurology and Psychiatry, Japan

[P3.124] TDCS increases activity in the frontotemporal cortex A. Katzorke*, A.K. Troeller, S. Löble, M. Möll, T. Polak, M.J. Herrmann, University of Würzburg, Germany

[P3.125] The detrimental impact of offline transcranial direct current stimulation of the right prefrontal cortex on long-term verbal associative memory performance A. Szollosi*

1, M. Marian

1, M. Zimmer

1, M. Racsmany

1 ,2,

1Budapest University of Technology and Economics,

Hungary, 2

Hungarian Academy of Sciences, Hungary

[P3.126] Transcranial direct current stimulation (tDCS) of the right inferior frontal gyrus attenuates sustained fear M.J. Herrmann*, B. Simons, T. Polak, University of Würzburg, Germany

[P3.127] Towards a personalised model for transcranial direct current stimulation (tDCS) A. Attard Trevisan*

1, M. Rotonda

1, L. Antigua

1, P. Cavallari

2,

1AAT Research, Malta,

2Universita Degli Studi Di

Milano, Italy

[P3.128] Numerical estimation of the current density and the associated temperature increase in the genital area during tsDCS S. Fiocchi*

1, P. Ravazzani

1, A. Priori

2, M. Parazzini

1,

1CNR Consiglio Nazionale delle Ricerche, Italy,

2Università

degli Studi di Milano, Italy

[P3.129] Higher tDCS gain in low performers in a verbal episodic memory task A. Habich*

1 ,2, S. Klöppel

1 ,2, J. Peter

1 ,2,

1University of Freiburg, Germany,

2University of Bern, Switzerland

[P3.130] COgnitive REhabilitation during transcranial Direct Current Stimulation (CORE-tDCS) for major or mild neurocognitive disorder patients - a protocol of a randomized controlled preliminary research T. Inagawa*, Y. Yokoi, M. Okazaki, K. Nakagome, National Center of Neurology and Psychiatry, Japan

[P3.131] Effects of bihemispheric tDCS combined with radial nerve stimulation in acute stroke patients S. Yagüe*

1 ,2, M. Veciana

1, J. Pedro

1, A. Martínez-Yélamos

1, H. Kumru

3, P. Cardona

1, B. Lara

1, B. García

3, J.

Montero1, J. Valls-Sole

4,

1Hospital Universitario de Bellvitge, Spain,

2Hospital Universitario Quirón-Dexeus,

Spain, 3

Hospital de Neurorehabilitación, Institut Guttmann, Spain, 4

Hospital Clínic, Spain

[P3.132] Impact of tDCS on executive functioning and executive domains L. Dumont*

1, S. El Mouderrib

1 ,3, H. Théoret

1 ,2,

1Universite de Montreal, Canada,

2Hôpital Ste-Justine,

Canada, 3

Université du Québec à Montréal, Canada

[P3.133] Lack of evidence between single transcranial direct current stimulation of dorsolateral prefrontal cortex and improvements in cognitive and attentional impulsivity E.H.G. Querino, J.J. de Paula, M.C. Valente e Silva, L.F. Malloy-Diniz, D.M. Miranda, M.A. Romano-Silva*, Universidade Federal de Minas Gerais, Brazil

[P3.134] The effect of cerebellar transcranial direct stimulation on language: a replication study K. Spielmann*

1 ,2, R. van der Vliet

1 ,2, W.M.E. van der Sandt-Koenderman

1 ,2, M.A. Frens

2 ,3, G.M. Ribbers

1 ,2,

R.W. Selles1 ,2

, S. van Vugt1, J.N. van der Geest

2, P. Holland

2 ,4,

1Rijndam rehabilitation institute, The

Netherlands, 2

Erasmus University Medical Center, The Netherlands, 3

Erasmus University College, The Netherlands,

4Ben-Gurion University of the Negev, Israel

[P3.136] Influence of high-definition anodal transcranial direct current stimulation (HD-atDCS) on motor learning of a high-speed bimanual task N.H. Pixa*, F. Steinberg, M. Doppelmayr, Johannes Gutenberg-University Mainz, Germany

[P3.137] Effectiveness of tDCS blinding protocol in a sham-controlled study W. Dinn*

1 ,2, F. Göral

2 ,3, S. Adigüzel

2, S. Karamürsel

4, F. Fregni

5, A. Aycicegi-Dinn

1 ,3,

1Istanbul 29 Mayis

University, Turkey, 2

Fatih University, Turkey, 3

Istanbul University, Turkey, 4

Istinye University, Turkey,

5Spaulding Rehabilitation Hospital, Harvard Medical School, USA

[P3.138] TDCS and memory function among individuals with or without elevated ADHD symptoms A. Aycicegi-Dinn*

1 ,2, F. Göral

2 ,3, S. Adigüzel

3, S. Karamürsel

4, W. Dinn

1 ,3,

1Istanbul 29 Mayis University,

Turkey, 2

Istanbul University, Turkey, 3

Fatih University, Turkey, 4

Istinye University, Turkey

[P3.139] Does transcranial direct current stimulation plus concurrent activity lessen dual task cost in people with Parkinson’s disease? C. Criminger, C. Swank, J. Mehta*, Texas Woman's University, USA


[P3.140] Combining transcranial direct current stimulation (tDCS) and classical extinction to persistently erase avoidance tendencies A. Ganho-Ávila*

1 ,2, O. Gonçalves

2 ,3, P. Boggio

5, M. Asthana

6, J. Almeida

1,

1University of Coimbra, Portugal,

2University of Minho, Portugal,


4Northeastern University, USA,

5Mackenzie

Presbyterian University, Brazil, 6

Indian Institute of Technology Kanpur, India

[P3.141] Electrophysiological mechanisms of tDCS modulation of executive functions L. Dubreuil-Vall*

1 ,2, P. Chau

2, A.S. Widge

2, G. Ruffini

1, J. Camprodon

2,

1Neuroelectrics, USA,

2Massachusetts

General Hospital, USA

[P3.142] Influence of COMT and NRG-1 gene polymorphisms on the effect of tDCS on Auditory Verbal Hallucinations in Schizophrenia H. Chhabra*, V. Shivakumar, M. Subbanna, A. Bose, M. Agrawal, V.S. Sreeraj, S.V. Kalmady, J.C. Narayanaswamy, M. Debnath, G. Venkatasubramanian, National Institute of Mental Health and Neurosciences, India

[P3.143] Memory enhancement in aging - the role of cognitive training combined with tDCS: Preliminary results L. Amaral*

1, A. Martins

1, J. Alves

1, F. Fernandes

1, F. Fregni

1, M. Simis

1, J. Almeida

1, M. Simões

1,

1University of

Coimbra, Portugal, 2

Centro Cérebro, Portugal, 3

HPA Saúde Private Health, Portugal, 4

Harvard Medical School, Portugal,

5University of Sao Paulo, Portugal

[P3.144] Effect of fronto-temporal transcranial direct current stimulation on corollary discharge in schizophrenia: A randomized, double-blind, sham-controlled study A. Bose*, H. Nawani, S.M. Agarwal, V. Shivakumar, J.C. Narayanaswamy, D. Kumar, G. Venkatasubramanian, National Institute of Mental Health and Neuro Sciences, India

[P3.146] Changes in fluid IQ after dorsolateral prefrontal cortex stimulation by tDCS is independent of changes in executive functioning J.J. de Paula, E.H.G. Querino, M.C. Valente e Silva, L.F. Malloy-Diniz, D.M. Miranda*, M.A. Romano-Silva, Universidade Federal de Minas Gerais, Brazil

[P3.147] Investigating speech processing through the brain-state-dependent stimulation framework: Effects of cathodal and anodal tDCS stimulation of the left inferior frontal gyrus (LIFG) on receptive and on productive language L.R. De Almeida*, P.C. Hansen, University of Birmingham, UK

[P3.148] Transcranial direct current stimulation (tDCS) enhances weight-bearing foot sole somatosensation in older adults J. Zhou

1 ,3, L. Lipsitz

1 ,3, J. Zhang

2, J. Fang

2, B. Manor*

1 ,3,

1Hebrew SeniorLife Institute for Aging Research,

USA, 2

Peking University, China, 3

Harvard Medical School, USA

[P3.149] Exploring the the neurophysiological effects of transcranial direct current stimulation over non-motor brain regions via EEG and TMS-EEG A.T. Hill*, N.C. Rogasch, P.B. Fitzgerald, K.E. Hoy, Monash University, Australia

[P3.150] Short- and long-term effects of anodal transcranial direct current stimulation on language learning in normal ageing G. Perceval*

1, A. Martin

1, D. Copland

1, M. Laine

2, K. Riggall

1, L. Ulm

1, M. Meinzer

1

1The University of Queensland Centre for Clinical Research (UQCCR), Australia,

2Abo Academi, Finland

[P3.151] Transcranial Direct Current Stimulation for Depression in Alzheimer's Disease Patient – preliminary data from the ongoing randomized controlled trial Y. Yokoi*

1, Z. Narita

1, T. Inagawa

1, T. Otsuka

2, M. Shibaoka

1, N. Miyagawa

1, K. Nakagome

1,

1National Center

of Neurology and Psychiatry, Japan, 2

Hiagari Hospital, Japan

[P3.152] Effect of single-session tDCS on cognition in Schizophrenia: A randomized double-blind cross-over study V.S. Sreeraj*, A. Bose, H. Chabbra, V. Shivakumar, S.M. Agarwal, C.N. Janardhanan, N.P. Rao, K. Muralidharan, S. Varambally, G. Venkatasubramanian, NIMHANS, India

[P3.153] Prefrontal cortex transcranial direct current stimulation increases parasympathetic nerve activity S. Nikolin*, T.W. Boonstra, C.K. Loo, D. Martin, UNSW, Australia

[P3.154] Cathodal high-definition transcranial direct current stimulation (HD-tDCS) over the dorsomedial prefrontal cortex increases frontal related negativity amplitude during reversal learning N. Albein-Urios*

1, H. Chase

2, M. Kirkovski

1, C. Davies

1, P. Enticott

1,

1Deakin University, Australia,

2University

ofPittsburgh, USA

[P3.155] Efficacy and safety of transcranial direct current stimulation associated to Virtual Reality and toAerobic Exercises program on the treatment of patients with fibromyalgia M. Herrera*, J. Monells, L. Miralles, M.J. Téllez, Neurodir, Spain


[P3.156] Effects of prefrontal transcranial direct current stimulation on language production in post-stroke aphasia M.I. Pestalozzi*

1, M. Di Pietro

2, G. Gaytanidis

2, L. Chouiter

3, L. Spierer

1, A. Schnider

2, J.M. Annoni

1, L.B.

Jost1,

1University of Fribourg, Switzerland,

2University Hospitals Geneva, Switzerland,

3Hôpital fribourgeois,

Switzerland

[P3.157] Effects of tDCS over Broca's area coupled with linguistic training are not specific to language. V. Zelenkova*, S. Malyutina, M. Feurra, National Research University Higher School of Economics, Russia

[P3.158] Influence of electrode configuration in neuromodulation of cervical spinal cord during non-invasive direct current stimulation S.R. Fernandes*

1, R. Salvador

1 ,2, C. Wenger

1 ,3, M. de Carvalho

1, P.C. Miranda

1,

1Universidade de Lisboa,

Portugal, 2

Neuroelectrics Barcelona, Spain, 3

Novocure, Ltd Haifa, Israel

[P3.159] New approaches for the treatment of morbid obesity: tDCS plus Cognitive Training (CT), a pilot study M. Castellano*

1, A. Cuenca-Royo

2, L. Forcano

2, A. Soria-Frisch

1, G. Ruffini

1 ,3, R. de la Torre

2,

1Starlab Inc.,

Spain, 2

Institut Hospital del Mar d’Investigacions Mediques (IMIM), Spain, 3

Neuroelectrics Corp, USA

[P3.160] Effects of anodal HD-tDCS or low-frequency rTMS on ipsilateral and contralateral M1 excitability: A pilot study V. Cabibel

1, J. Froger

1 ,2, M. Muthalib*

1 ,3, S. Perrey

1,


2CHU Nîmes, France,

3Deakin University, Australia

[P3.161] Transcranial direct current stimulation effects in attention-deficit/hyperactivity disorder M. DiBiasi

2, L. Moura

2, E. Pirolla

3 ,2, V. Lima

4 ,2, L.C. Grecco

4 ,5, M. Muszkat

4, E.P. Sena

1, C. Cosmo*

1 ,2,

1Federal



Sirio Libanês Hospital, Brazil, 4

Federal University of São Paulo, Brazil,

5Pediatric Neurosurgical Center - Rehabilitation (CENEPE), Brazil

[P3.162] Transcranial direct current stimulation for the treatment of auditory hallucinations of schizophrenia P. Pondé

3, E.P. Sena

1, J.A. Camprodon

1, A.N. Araujo

1, M. Ferrari-Neto

1, M. DiBiasi

2, A. Baptista

1, L. Moura

2, C.

Camila*1 ,2

, 1Federal University of Bahia, Brazil,


3Bahiana School of Medicine

and Public Health, Brazil

[P3.163] Effects of vagus nerve stimulation on sleep-related breathing in epilepsy patients J. Miro*

1,2, N. Salord

1, S. Jaraba

1, M. Santurino

1, G. Plans

1, C. Monasterio

1, M. Falip

1

1Hospital Universistari de Bellvitge, Spain,

2Universitat de Barcelona, Spain

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