Changes for page SGA3 D1.5 Showcase 1

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29 29  )))
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32 -The Showcase 1 aimed at investigations related to variability in neuroscience from two perspectives: (a) the interpersonal variability studied by the virtual ageing study, and (b) the variability across different cortical regions within an individual brain.
32 +The virtual ageing study is described in detail in following publication:
33 33  
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35 -== (a) Interpersonal variability—virtual ageing ==
36 -
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38 -See the details of the first study in the following publication:
39 -
40 40  M. Lavanga, J. Stumme, B. H. Yalcinkaya, J. Fousek, C. Jockwitz, H. Sheheitli, N. Bittner, M. Hashemi, S. Petkoski, S. Caspers, and V. Jirsa, [[The Virtual Aging Brain: A Model-Driven Explanation for Cognitive Decline in Older Subjects>>https://doi.org/10.1101/2022.02.17.480902]].
41 41  
42 -=== Simulation of resting-state activity ===
36 +== Simulation of resting-state activity ==
43 43  
44 44  The fist notebook in the inter-individual variability workflow explores the resting-state simulation for a subject of the 1000BRAINS dataset. Functional data are simulated by means of a brain network model implemented in TVB, which is an ensemble of neural mass models linked via the weights of the structural connectivity (SC) matrix. Following topics are covered:
45 45  
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54 54  
55 55  [[image:image-20220103100841-2.png]]
56 56  
57 -=== Virtual ageing trajectories ===
51 +== Virtual ageing trajectories ==
58 58  
59 59  The second steps shows the investigation of virtual ageing trajectory for each subject. In this context, we are going to show:
60 60  
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68 68  
69 69  [[image:image-20220103101022-3.png]]
70 70  
71 -=== Inference with SBI ===
65 +== Inference with SBI ==
72 72  
73 73  The last step of the inter-individual variability workflow employs Simulation Based Inference for estimation of the full posterior values of the parameters. Here, a deep neural estimator is trained to provide a relationship between the parameters of a model (black box simulator) and selected descriptive statistics of the observed data.
74 74  
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78 78  
79 79  * [[virtual_ageing/notebooks/3_inference_with_SBI.ipynb>>https://lab.ch.ebrains.eu/user-redirect/lab/tree/shared/SGA3%20D1.2%20Showcase%201/virtual_ageing/notebooks/3_inference_with_SBI.ipynb]]
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82 -== (b) Regional variability ==
75 +== Regional variability data ==
83 83  
84 -Aims at demonstrating the construction of whole-brain network models of the brain's activity accounting for differences in receptor densities across cortical regions.
77 +The first step of the regional variability workflow consists in loading the data from the Knowledge Graph, including the regional bias on the model. In this case we require:
85 85  
86 -=== Loading the data from EBRAINS ===
87 -
88 -The first step of this workflow consists in loading the data from the Knowledge Graph via the //siibra interface//, including the regional bias on the model. In this case we require:
89 -
90 90  1. Structural connectivity matrices,
91 -1. GABAa and AMPA receptor densities for each brain region, and
80 +1. GABA and AMPA receptor densities for each brain region, and
92 92  1. empirical resting-state fMRI data for fitting and validation of the simulations. The three datasets shall be characterised in the same parcellation.
93 93  
94 94  Link to the notebook: