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From version 4.1
edited by pierstanpaolucci
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edited by pierstanpaolucci
on 2021/09/21 15:37
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Summary

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Title
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1 -Interactive Exploration of Brain States and Spatio Temporal Activity Patterns in Data-Constrained Simulations
1 +Interactive Exploration of Brain States and Spatio-Temporal Activity Patterns in Data-Constrained Simulations
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2 2  (((
3 3  (% class="container" %)
4 4  (((
5 -= My Collab's Extended Title =
5 += Interactive Exploration of Brain States and Spatio-Temporal Activity Patterns in Data-Constrained Simulations =
6 6  
7 -My collab's subtitle
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8 +
9 +Explore brain states and spatio-temporal cortical activity patterns on your own
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9 9  )))
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13 13  (% class="col-xs-12 col-sm-8" %)
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15 -= What can I find here? =
17 += Open the Lab link on the left to launch the interactive simulation =
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17 -* Notice how the table of contents on the right
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19 -* to hold this page's headers
19 +How the same network can generate different brain states with their specific propagation patterns and rhythms?
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21 -= Who has access? =
21 +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.
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23 -Describe the audience of this collab.
23 +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.
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25 +The connectivity of the model was inferred from cortical activity acquired using GECI imaging technique. Even if the connectivity of the model was inferred from a single brain-state, the neuromodulated model supports the emergence of a rich dynamic repertoire of spatio-temporal propagation patterns, from those corresponding to deepests levels of anesthesia (spirals) to classical postero-anterior and rostro-caudal waves up to the transition to asynchronous activity, with the dissolution of the slow-wave features (1).
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27 +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)
28 +
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
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31 += =
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