Untitled - Laboratory of Neurophysics and Physiology

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P179 P180 P181 P182 Neural Field Simulator: fast computation and 3D-visualization Eric Nichols ⋆ , Axel Hutt INRIA CR Nancy - Grand Est, Equipe NEUROSYS, 615 rue du Jardin Botanique, 54602 Villers-les- Nancy, France Theoretical model for neurovascular coupling via interactions of NO, EET, and 20-HETE Hyuk Kang 1⋆ , Jung-Min Lee 1 , Misun Kim 2 , and Dong-Uk Hwang 1 1 National Institutes for mathematical Sciences, Daejeon, Republic of Korea, 305-811 2 Department of Electrical Engineering, Korea Advanced Institute of Science and Technology, Daejeon, Republic of Korea, 305-701 Prediction was predictable from human brain activity in fronto-parietal cortex Yumi Shikauchi 1,2⋆ , Shin Ishii 1,2 1 Graduate School of Informatics, Kyoto University, Gokasho, Uji, Kyoto 611-0011, Japan 2 ATR Neural Information Analysis Laboratories, 2-2-2 Hikaridai Seika-cho, Sorakugun, Kyoto, 619- 0288 Japan Pairwise correlation graphs from hippocampal population activity have highly nonrandom, low-dimensional clique topology Carina Curto 1 , Chad Giusti 1 , Keler Marku 1 , Eva Pastalkova 2 , and Vladimir Itskov 1⋆ 1 Department of Mathematics, University of Nebraska-Lincoln, Lincoln, NE, USA 2 Janelia Farm Research Campus, HHMI, Ashburn, VA 20147, USA P183 P184 P185 Emergence of Bottom-up Saliency in a Spiking Model of V1 Botond Szatmary ⋆ , Micah Richert, Jayram Nageswaran, Csaba Petre, Filip Piekniewski, Sach Sokol, and Eugene M. Izhikevich Brain Corporation, San Diego, CA 92121, USA Balanced excitation and inhibition in a spiking model of V1 Filip Piekniewski 1⋆ , Micah Richert 1 , Dimitry Fisher 1 , Botond Szatmary 1 , Csaba Petre 1 , Sach Sokol 2 , and Eugene M. Izhikevich 1 1 Brain Corporation, San Diego, CA 92121, USA 2 Department of Neuroscience and The Zanvyl Krieger Mind/Brain Institute Johns Hopkins University, Baltimore, MD, USA A Spiking model of Superior Colliculus for Bottom-Up Saliency Micah Richert 1 , Jayram Nageswaran 1⋆ , Sach Sokol 2 , Botond Szatmary 1 , Csaba Petre 1 , Filip Piekniewski 1 , and Eugene M. Izhikevich 1 1 Brain Corporation, San Diego, CA 92121, USA 2 Mind Brain Institute, John Hopkins University, Baltimore, MD 21218, USA 132
P186 Latency and rate coding in a spiking model of retina Dimitry Fisher ⋆ , Csaba Petre, Botond Szatmary, Marius Buibas, and Eugene M. Izhikevich Brain Corporation, San Diego CA P187 Beyond inhibition: lateral modulation of plasticity of feedforward synapses in a spiking model of V1 Csaba Petre ⋆ , Micah Richert, Botond Szatmary, and Eugene M. Izhikevich Brain Corporation, San Diego, CA, 92121, USA P188 Temporally evolving surround suppression helps decoding in a spiking model of motion processing Philip Meier ⋆ , Micah Richert, Jayram Nageswaran, and Eugene M. Izhikevich Brain Corporation, San Diego, California 92121, USA P189 Self-tuning spike-timing dependent plasticity curves to simplify models and improve learning Micah Richert ⋆ , Botond Szatmary, and Eugene M. Izhikevich Brain Corporation, San Diego P190 Full-scale structural model of the Inferior Olive and Olivocerebellar projection constructed from constraining meshes and directed growth James Kozloski ⋆ , Gurev Viatcheslav Computational Biology Center, IBM T.J. Watson Research Center, Yorktown Heights, NY, USA P191 Denervation-induced dendritic reorganization leads to changes in the electrotonic architecture of model dentate granule cells Steffen Platschek 1⋆ , Hermann Cuntz 1,2 , Mario Vuksic 3 , Thomas Deller 1 , and Peter Jedlicka 1 1 Institute of Clinical Neuroanatomy, Neuroscience Center, Goethe-University, Frankfurt/Main, D- 60590, Germany 2 Ernst Strüngmann Institute for Neuroscience in Cooperation with Max Planck Society, Frankfurt/Main, D-60528, Germany 3 Croatian Institute for Brain Research, School of Medicine, University of Zagreb, Zagreb, HR-10000, Croatia P192 The roles of short-term plasticity and synaptic weights in self-organized criticality Kim Hoon-Hee ⋆ , Jaeseung Jeong Department of Bio and Brain Engineering, KAIST, Daejeon, South Korea 133
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Contents Overview 5 OCNS - The Orga
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Organization for Computational Neur
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CNS*2013 Sponsors Brain Corporation
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General Info At the Meeting Venue T
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Local Information Since a list of a
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• You have a nice 360°-view over
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Gala Diner The gala diner will take
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Tutorials T1 Neural-mass and neural
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Main Meeting 25
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Oral session II: Visual system 14:0
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Tuesday July 16 9:00 - 9:10 Announc
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Workshops Note: W21 will be held Th
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W10 New approaches to spike train a
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Abstracts
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makes generalised seizures more lik
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• a scheme for biophysically deta
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• Pecevski et al. (2011), Probabi
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[5] Goodman (2010), Code generation
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eview key theoretical results and p
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Simon Laughlin Department of Zoolog
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Contributed Talks F1 Consistency re
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activation phase locks in the senso
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tigated whether eCBs could also pro
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2. Kobayashi R, Shinomoto S, Lansky
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O5 We now know what fly photorecept
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(B.Stem). The retina covers 10 by 1
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internally generated propagating wa
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We examine spike-count correlations
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Our results predict that thermosens
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corresponding experimental observat
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Figure 1: Properties of the model (
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goal-directed movements. Here, seve
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escence. In the low connectivity re
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O21 Multiscale modeling of cortical
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evidence [4]. We show here that the
Page 82 and 83: • How can one distinguish and stu
Page 84 and 85: network model in realtime W4 Method
Page 86 and 87: Rita Almeida, Karolinska Institute;
Page 88 and 89: greater detail. For example, dendri
Page 90 and 91: effective processing of task-relate
Page 92 and 93: W14 Modeling general anesthesia: fr
Page 94 and 95: Arvind Kumar, Freiburg: Basal gangl
Page 96 and 97: Morten Kringelbach, Oxford Maxime G
Page 99 and 100: Posters
Page 101 and 102: Posters Sunday Posters Posters P1 -
Page 103 and 104: P11 The role of inhibition in the g
Page 105 and 106: P25 P26 P27 P28 Estimating the frac
Page 107 and 108: P37 Zero-Lag Synchronization in Cor
Page 109 and 110: P48 Requirements for the Robust Ope
Page 111 and 112: P59 A maximum likelihood estimator
Page 113 and 114: P72 P73 The behavior of the electri
Page 115 and 116: P84 Multistability in large scale m
Page 117 and 118: P96 A biophysical model of cerebell
Page 119 and 120: P105 Estimating the transfer functi
Page 121 and 122: P117 P118 Neuronal Coding in the Ro
Page 123 and 124: P128 P129 P130 P131 P132 P133 P134
Page 125 and 126: P141 Visually guided behavior in fr
Page 127 and 128: P151 P152 P153 P154 Estimation of n
Page 129 and 130: P163 From laptops to supercomputers
Page 131: P173 Single cell neuro-sensory dyna
Page 135 and 136: P200 On the influence of inhibitory
Page 137 and 138: P213 Estimating synaptic connection
Page 139 and 140: P228 Controlling the Go / No-Go dec
Page 141 and 142: P240 P241 P242 P243 P244 P245 P246
Page 143 and 144: P254 Motion control of thumb and in
Page 145 and 146: P267 Non-instantaneous synaptic tra
Page 147 and 148: P280 P281 Trial by trial decoding o
Page 149 and 150: 149
Page 151 and 152: P297 A numerical renormalisation gr
Page 153 and 154: P309 Detection of neuronal signatur
Page 155 and 156: P321 Long-Term Potentiation Through
Page 157 and 158: P334 Sparse coding model captures V
Page 159 and 160: P347 Influence of biophysical prope
Page 161 and 162: P360 Plasticity of Network Dynamics
Page 163 and 164: P373 The implications of evolutiona
Page 165 and 166: P386 Attractor dynamics in local ne
Page 167 and 168: P398 Why are all phase resetting cu
Page 169 and 170: P410 Prefrontal cortical modulation
Page 171 and 172: P422 Olfactory bulb network dynamic
Page 173 and 174: P435 Center-Surround Interactions i
Page 175 and 176: Appendix
Page 177 and 178: Notes 177
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183
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Page Index A Aazhang, Behnaam . . .
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Chavane, Frederic . . . . . . . . .
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Gerhard, Felipe . . . . . . . . . .
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Kömek, Kübra. . . . . . . . . . .
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Muresan, Raul Cristian. . . . . . .
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Rotstein, Horacio G. . . . . . . .
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V Valderrama, Mario . . . . . . . .
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Contributions Index A Aazhang, Behn
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Chartier, Josh . . . . . . . . . .
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Gekas, Nikos . . . . . . . . . . .
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Knösche, Thomas . . . . . . . . .
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Mosqueiro, Thiago . . . . . . . . .
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Ronacher, Bernhard . . . . . . . .
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Tsigankov, Dmitry. . . . . . . . .
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