Analytical Operations Relate Structural and Functional Connectivity in the Brain

Resting-state large-scale brain models vary in the amount of biological elements they incorporate and in the way they are being tested. One might expect that the more realistic the model is, the closer it should reproduce real functional data. It has been shown, instead, that when linear correlation...

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Bibliographic Details
Published in:PloS one 2016-08, Vol.11 (8), p.e0157292
Main Authors: Saggio, Maria Luisa, Ritter, Petra, Jirsa, Viktor K
Format: Article
Language:English
Subjects:
Analysis
Automation
Biology and Life Sciences
Brain
Brain - anatomy & histology
Brain - diagnostic imaging
Brain - physiology
Brain mapping
Cellular signal transduction
Cognitive science
Computer and Information Sciences
Computer simulation
Data processing
Exploration
Functional magnetic resonance imaging
Functional Neuroimaging
Humans
Information retrieval
Magnetic Resonance Imaging
Medical imaging
Medicine and Health Sciences
Models, Neurological
Neural networks
Neural Pathways - anatomy & histology
Neural Pathways - physiology
Neuroscience
Neurosciences
Physical Sciences
Research and Analysis Methods
Structure-function relationships
Substantia alba
Time series
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Summary:Resting-state large-scale brain models vary in the amount of biological elements they incorporate and in the way they are being tested. One might expect that the more realistic the model is, the closer it should reproduce real functional data. It has been shown, instead, that when linear correlation across long BOLD fMRI time-series is used as a measure for functional connectivity (FC) to compare simulated and real data, a simple model performs just as well, or even better, than more sophisticated ones. The model in question is a simple linear model, which considers the physiological noise that is pervasively present in our brain while it diffuses across the white-matter connections, that is structural connectivity (SC). We deeply investigate this linear model, providing an analytical solution to straightforwardly compute FC from SC without the need of computationally costly simulations of time-series. We provide a few examples how this analytical solution could be used to perform a fast and detailed parameter exploration or to investigate resting-state non-stationarities. Most importantly, by inverting the analytical solution, we propose a method to retrieve information on the anatomical structure directly from functional data. This simple method can be used to complement or guide DTI/DSI and tractography results, especially for a better assessment of inter-hemispheric connections, or to provide an estimate of SC when only functional data are available.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0157292