Abstract
Naturalistic functional magnetic resonance imaging (NfMRI) has become an effective tool to study brain functional activities in real-life context, which reduces the anxiety or boredom due to difficult or repetitive tasks and avoids the problem of unreliable collection of brain activity caused by the subjects’ microsleeps during resting state. Recent studies have made efforts on characterizing the brain’s hierarchical organizations from fMRI data by various deep learning models. However, most of those models have ignored the properties of group-wise consistency and inter-subject difference in brain function under naturalistic paradigm. Another critical issue is how to determine the optimal neural architecture of deep learning models, as manual design of neural architecture is time-consuming and less reliable. To tackle these problems, we proposed a two-stage deep belief network (DBN) with neural architecture search (NAS) combined framework (two-stage NAS-DBN) to model both the group-consistent and individual-specific naturalistic functional brain networks (FBNs), which reflected the hierarchical organization of brain function and the nature of brain functional activities under naturalistic paradigm. Moreover, the test-retest reliability and spatial overlap rate of the FBNs identified by our model reveal better performance than that of widely used traditional methods. In general, our model provides a promising method for characterizing hierarchical spatiotemporal features under the natural paradigm.
Highlights
Neuroscientists have long realized that functional brain networks (FBNs) present varying degrees of activation responses in a multi-scale hierarchical structure (Ferrarini et al, 2009)
We proposed a two-stage neural architecture search (NAS)-deep belief network (DBN) framework to derive group-level and individual-level spatio-temporal patterns from Naturalistic functional magnetic resonance imaging (NfMRI) signals, offering one of the first applications of NAS-DBN framework for analyzing dynamic naturalistic fMRI data
Compared with other FBNs detection frameworks based on deep learning models, the proposed model can characterize hierarchical organization of FBNs and associated temporal features under naturalistic condition, which is an intrinsic nature of brain function and can be revealed by our experimental results
Summary
Neuroscientists have long realized that functional brain networks (FBNs) present varying degrees of activation responses in a multi-scale hierarchical structure (Ferrarini et al, 2009). It is unclear whether and to what extent such task paradigms could uncover the complex mental processes in real life. To address limitations of traditional task and resting state paradigms, recent studies employ naturalistic paradigms, such as movie viewing, which examine the complex neural processes during dynamic, naturally engaging stimuli that greatly resembles the brain function under real-life condition (Sonkusare et al, 2019). Brain activities under naturalistic paradigms are always dynamic and complex with their distinctive properties (Sonkusare et al, 2019), causing difficulty to model their neural correlates and awaiting appropriate computational framework
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