TempoCave: Visualizing Dynamic Connectome Datasets to Support Cognitive Behavioral Therapy

Xu, Ran; Thomas, Manu Mathew; Leow, Alex D.; Ajilore, Olusola; Forbes, Angus G.

doi:10.1109/visual.2019.8933544

Cited by 4 publications

(5 citation statements)

References 39 publications

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“…As an illustrative example, we consider the problem of 3D edge bundling in complex network visualization (Bach et al, 2017;Ferreira et al, 2018;Holten & Van Wijk, 2009). We used MCPM to fit and visualize a human brain connectome (Xu et al, 2019), a set of 105 high-level nodes representing different subregions of the brain (so-called modes). To simplify this experiment (Figure 29), we disregard the connectome edges and simply weigh each node by its overall connectivity strength.…”

Section: Temporally Varying Datamentioning

confidence: 99%

Monte Carlo Physarum Machine: Characteristics of Pattern Formation in Continuous Stochastic Transport Networks

et al. 2022

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We present Monte Carlo Physarum Machine (MCPM): a computational model suitable for reconstructing continuous transport networks from sparse 2D and 3D data. MCPM is a probabilistic generalization of Jones's (2010) agent-based model for simulating the growth of Physarum polycephalum (slime mold). We compare MCPM to Jones's work on theoretical grounds, and describe a task-specific variant designed for reconstructing the large-scale distribution of gas and dark matter in the Universe known as the cosmic web. To analyze the new model, we first explore MCPM's self-patterning behavior, showing a wide range of continuous network-like morphologies—called polyphorms—that the model produces from geometrically intuitive parameters. Applying MCPM to both simulated and observational cosmological data sets, we then evaluate its ability to produce consistent 3D density maps of the cosmic web. Finally, we examine other possible tasks where MCPM could be useful, along with several examples of fitting to domain-specific data as proofs of concept.

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Section: Temporally Varying Datamentioning

confidence: 99%

Monte Carlo Physarum Machine: Characteristics of Pattern Formation in Continuous Stochastic Transport Networks

et al. 2022

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“…Research on visual network comparison has mainly focused on the development of practical approaches, e.g. for specific types of networks [33,53,55,57,66], and for structural overviews by abstraction or aggregation, see e.g. [10,35,67].…”

Section: Network Comparison and Visualization Metaphorsmentioning

confidence: 99%

“…Recent work includes both application-oriented research, e.g. in the context of connectome and brain activity analysis [50,66], and more fundamental investigations, e.g. on navigation [23,60], the influence of encodings [14], or the difference between immersive environments [17].…”

Section: Network Comparison and Visualization Metaphorsmentioning

confidence: 99%

“…Research related to fMRI data comes with certain challenges and demands that can be mainly abstracted to different comparison tasks regarding weighted graphs [1,18,33,66]. Alper et al made use of a literature survey and individual expert interviews with seven experts to determine the main challenges that neuroscientists have to solve when dealing with fMRI comparison [1].…”

Section: Tasksmentioning

confidence: 99%

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Visual Comparison of Networks in VR

Joos

Jaeger-Honz

Schreiber

et al. 2022

IEEE Trans. Visual. Comput. Graphics

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“…Network-based neuroscience visualization tools have demonstrated how to gain insight from connectome datasets, some at the level of functional modules, e.g. NeuroCave [16] and Tem-poCave [33], and some at the level of individual neurons, e.g. Brain-Trawler [8].…”

Section: Visual Analytics In Neuroimagingmentioning

confidence: 99%

PRAGMA: Interactively Constructing Functional Brain Parcellations

Bayrak¹,

Nhung²,

Hansen³

et al. 2020

Preprint

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Figure 1: PRAGMA is an interactive tool for constructing scan-specific brain parcellations from mainstream atlases. Its interface incorporates five complementary visuals: (A) abstract view of the hierarchical clustering of the brain through a node-link diagram, (B1) similarity of fMRI signal time-courses represented with a line plot with a shaded confidence interval, (B2) homogeneity glyphs within nodes, (C1) functional connectivity depicted as a chord diagram and (C2) anatomical location of parcels viewed on an orthographic template.

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TempoCave: Visualizing Dynamic Connectome Datasets to Support Cognitive Behavioral Therapy

Cited by 4 publications

References 39 publications

Monte Carlo Physarum Machine: Characteristics of Pattern Formation in Continuous Stochastic Transport Networks

Monte Carlo Physarum Machine: Characteristics of Pattern Formation in Continuous Stochastic Transport Networks

Visual Comparison of Networks in VR

PRAGMA: Interactively Constructing Functional Brain Parcellations

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