AI Article Synopsis
- Recent research highlights the variability over time (temporal non-stationarity) of brain connectivity patterns in resting state fMRI scans.
- A new method utilizing Hidden Markov Modeling (HMM) decodes these connectivity changes into distinct hidden "states" characterized by unique covariance matrices associated with whole-brain networks.
- Testing on simulated and normative fMRI data demonstrates that the model can identify both the underlying brain network structures and their fluctuating states during scanning.
Article Abstract
Research in recent years has provided some evidence of temporal non-stationarity of functional connectivity in resting state fMRI. In this paper, we present a novel methodology that can decode connectivity dynamics into a temporal sequence of hidden network "states" for each subject, using a Hidden Markov Modeling (HMM) framework. Each state is characterized by a unique covariance matrix or whole-brain network. Our model generates these covariance matrices from a common but unknown set of sparse basis networks, which capture the range of functional activity co-variations of regions of interest (ROIs). Distinct hidden states arise due to a variation in the strengths of these basis networks. Thus, our generative model combines a HMM framework with sparse basis learning of positive definite matrices. Results on simulated fMRI data show that our method can effectively recover underlying basis networks as well as hidden states. We apply this method on a normative dataset of resting state fMRI scans. Results indicate that the functional activity of a subject at any point during the scan is composed of combinations of overlapping task-positive/negative pairs of networks as revealed by our basis. Distinct hidden temporal states are produced due to a different set of basis networks dominating the covariance pattern in each state.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3974209 | PMC |
| http://dx.doi.org/10.1007/978-3-642-38868-2_36 | DOI Listing |
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