期刊
NEUROIMAGE
卷 279, 期 -, 页码 -出版社
ACADEMIC PRESS INC ELSEVIER SCIENCE
DOI: 10.1016/j.neuroimage.2023.120329
关键词
Resting-state fMRI; Group Surrogate Data Generating Model; Multivariate Time-series Ensemble Similarity; Score; Vector Auto-Regressive Deep Neural Network; Marmoset; State transition analysis
This study advances non-invasive brain analysis through novel approaches, such as big data analytics and in silico simulation. The researchers developed a Group Surrogate Data Generating Model (GSDGM) to generate biologically plausible human brain dynamics and a Multivariate Time-series Ensemble Similarity Score (MTESS) to measure similarity between multivariate time-series. These techniques were successfully applied to fingerprint analysis of resting-state brain data, distinguishing normal and outlier sessions.
Advancements in non-invasive brain analysis through novel approaches such as big data analytics and in silico simulation are essential for explaining brain function and associated pathologies. In this study, we extend the vector auto-regressive surrogate technique from a single multivariate time-series to group data using a novel Group Surrogate Data Generating Model (GSDGM). This methodology allowed us to generate biologically plausible human brain dynamics representative of a large human resting-state (rs-fMRI) dataset obtained from the Human Connectome Project. Simultaneously, we defined a novel similarity measure, termed the Multivariate Time-series Ensemble Similarity Score (MTESS). MTESS showed high accuracy and f-measure in subject identification, and it can directly compare the similarity between two multivariate time-series. We used MTESS to analyze both human and marmoset rs-fMRI data. Our results showed similarity differences between cortical and subcortical regions. We also conducted MTESS and state transition analysis between single and group surrogate techniques, and confirmed that a group surrogate approach can generate plausible group centroid multivariate time-series. Finally, we used GSDGM and MTESS for the fingerprint analysis of human rs-fMRI data, successfully distinguishing normal and outlier sessions. These new techniques will be useful for clinical applications and in silico simulation.
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