Changes for page Interactive Exploration of Brain States and Spatio-Temporal Activity Patterns in Data-Constrained Simulations
Last modified by pierstanpaolucci on 2023/06/29 18:29
From version 17.1
edited by pierstanpaolucci
on 2021/09/22 10:46
on 2021/09/22 10:46
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To version 13.3
edited by pierstanpaolucci
on 2021/09/22 10:35
on 2021/09/22 10:35
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... ... @@ -3,10 +3,7 @@ 3 3 (% class="container" %) 4 4 ((( 5 5 (% class="lead" id="HInteractiveExplorationofBrainStatesandSpatio-TemporalActivityPatternsinData-ConstrainedSimulations" %) 6 -Open the Lab link on the left to 7 - 8 -(% class="lead" %) 9 -Explore brain states and spatio-temporal cortical activity patterns on your own 6 +(% style="color: rgb(243, 156, 18); background-color: rgb(255, 255, 255)" %)Explore brain states and spatio-temporal cortical activity patterns on your own 10 10 ))) 11 11 ))) 12 12 ... ... @@ -14,8 +14,11 @@ 14 14 ((( 15 15 (% class="col-xs-12 col-sm-8" %) 16 16 ((( 17 -**How the same network can generate different brain states with their specific propagation patterns and rhythms?** 14 +(% class="lead" id="HOpentheLablinkonthelefttolaunchtheinteractivesimulation" %) 15 +Open the Lab link on the left to launch the interactive simulation 18 18 17 +How the same network can generate different brain states with their specific propagation patterns and rhythms? 18 + 19 19 In this Jupyter Lab the user can interactively change the neuromodulated fatigue parameters and observe in real-time the emergence of different categories of slow- wave wave-propagation patterns and the transition to an asynchronous regime on a columnar mean-field model equipped with lateral connections inferred from experimentally acquired cortical activity. 20 20 21 21 The model displays the dorsal view of a mouse cortical hemisphere sampled by pixels of 100-micron size over a 25 mm2 field of view. ... ... @@ -24,17 +24,14 @@ 24 24 25 25 The experimental data set from which the model has been inferred has been provided by LENS and it is available in the EBRAINS KG (2) 26 26 27 -The predecessor of this model can be found at (3) 28 - 29 29 (1) Capone, C. et al. (2021) “Simulations Approaching Data: Cortical Slow Waves in Inferred Models of the Whole Hemisphere of Mouse” arXiv:2104.07445 [[https:~~/~~/arxiv.org/abs/2104.07445>>https://arxiv.org/abs/2104.07445]] 30 30 31 31 (2) Resta, F., Allegra Mascaro, A. L., & Pavone, F. (2020). //Study of Slow Waves (SWs) propagation through wide-field calcium imaging of the right cortical hemisphere of GCaMP6f mice// [Data set]. EBRAINS. [[DOI: 10.25493/3E6Y-E8G>>url:https://doi.org/10.25493%2F3E6Y-E8G]] 32 32 33 -(3) Mean Field Simulation of whole mouse hemisphere with parameters inferred from optical recordings [[https:~~/~~/search.kg.ebrains.eu/instances/e572362f-9461-4f9d-81e2-b69cd44185f4>>https://search.kg.ebrains.eu/instances/e572362f-9461-4f9d-81e2-b69cd44185f4]] 34 - 35 35 = = 36 36 ))) 37 37 34 + 38 38 (% class="col-xs-12 col-sm-4" %) 39 39 ((( 40 40 {{box title="**Contents**"}}