A Primer on Topological Data Analysis and Graph Signal Processing for Neuroimaging Data
Thursday, June 6, 2024 – 4:00 pm - 5:30 pm: Online
Thursday, June 13, 2024 – 4:00 pm - 5:30 pm: Online
Thursday, June 20, 2024 – 4:00 pm - 6:00 pm: Online
Thursday, June 27, 2024 – 4:00 pm - 6:00 pm: Online
Contact helen.pushkarskaya@yale.edu
Dr. Dhananjay Bhaskar, Postdoctoral Researcher, Department of Genetics, Yale School of Medicine
What?
GSTH was originally developed to quantify the Ca2+ signaling dynamics of stem cells in the mouse epidermis. We later adapted it for applications in neuroscience. The technique is generally applicable to any biophysical system that exhibits complex spatiotemporal dynamics. Using techniques from topological data analysis and geometry, GSTH produces quantitative readouts that capture the overall shape of the dynamic trajectories, thus enabling the identification of ‘neural motifs’ (patterns of neural activity) associated with different stimuli, tasks and neurological disorders.
June 6, 4:00 pm - 5:30 pm, Dhananjay Bhaskar, PhD, Yale School of Medicine
In the first session, we will give an overview of aims and basics of topological data analysis.
Online
June 13, 4:00 pm - 5:30 pm, Rahul Singh, PhD, Yale Wu Tsai Neuroscience Institute, Yale University
In the second session, we will introduce graph signal processing methods.
Online
June 20, 4:00 pm - 6:00 pm, Dhananjay Bhaskar, PhD, Yale School of Medicine
Brian Zaboski, PhD, Yale School of Medicine
In the third session, we will introduce the Geometry Scattering Trajectory Homology (GSTH) approach and discuss some applications for clinical research.
Online
June 20, 4:00 pm - 6:00 pm, Dhananjay Bhaskar, PhD, Yale School of Medicine
Rahul Singh, PhD, Yale Wu Tsai Neuroscience Institute
The fourth session will be the practical tutorial in GSTH using real data.
Online
Note: If you are interested in attending the practical tutorial in GSTH (session 4) please contact helen.pushkarskaya@yale.edu).
All recordings will be posted online.
Why?
Geometry Scattering Trajectory Homology (GSTH) for Neuroimaging Data has three key strengths.
First, while other techniques for analyzing brain dynamics (e.g. wavelet coherence, phase analysis, granger causality) operate solely in the spatial or temporal domain, GSTH uses graph wavelet analysis to capture spatial information and topological data analysis to capture temporal information simultaneously. This facilitates more comprehensive understanding of complex neural dynamics in a data driven way.
Second, GSTH enables dimensionality reduction to generate easily interpretable low-dimensional trajectories of brain activity from neuroimaging data, e.g. EEG, fNIRS, and fMRI.
Third, GSTH can be used to examine a long-duration spatiotemporal dynamics on an individual level, and, thus, enables evaluating within-subject changes in neural patterns in relation to fluctuation of symptom severity or following treatment
How?
Prerequisites:
- Basic programming skills in Python (open source),
- Fundamentals of functional MRI
- Basic understanding of matrix algebra and frequency analysis
- Basic understanding of graph spectral theory and topological data analysis (both are covered in this series).
Required Tools:
- Python (open source)
- We will use Google Collab (free) in the hands-on tutorial.
Tutorials:
- Foundations of topological data analysis: here
-
Graph Signal Processing Resources: here
Datasets:
- GSTH can be used to analyze multiple neuroimaging modalities, including EEG, MEG, fMRI, and fNIRS
- In this workshop series, participants will learn to use GSTH using open-source, publicly available from OpenNeuro.
Reference publications:
- Signaling dynamics of stem cells in the mouse epidermis (PEB): Moore, J.L., et al., 2023. Cell cycle controls long-range calcium signaling in the regenerating epidermis. Journal of Cell Biology, 222(7), pp.1-20.
- GSTH applications to cellular data (PEB): Bhaskar, D., 2023. Capturing Spatiotemporal Signaling Patterns in Cellular Data with Geometric Scattering Trajectory Homology. BioRxiv: 2023-03.