Abstract
ObjectiveResting-state functional magnetic resonance imaging (rs-fMRI) has become an essential measure to investigate the human brain’s spontaneous activity and intrinsic functional connectivity. Several studies including our own previous work have shown that the brain controls the regulation of energy expenditure and food intake behavior. Accordingly, we expected different metabolic states to influence connectivity and activity patterns in neuronal networks.MethodsThe influence of hunger and satiety on rs-fMRI was investigated using three connectivity models (local connectivity, global connectivity and amplitude rs-fMRI signals). After extracting the connectivity parameters of 90 brain regions for each model, we used sequential forward floating selection strategy in conjunction with a linear support vector machine classifier and permutation tests to reveal which connectivity model differentiates best between metabolic states (hunger vs. satiety).ResultsWe found that the amplitude of rs-fMRI signals is slightly more precise than local and global connectivity models in order to detect resting brain changes during hunger and satiety with a classification accuracy of 81%.ConclusionThe amplitude of rs-fMRI signals serves as a suitable basis for machine learning based classification of brain activity. This opens up the possibility to apply this combination of algorithms to similar research questions, such as the characterization of brain states (e.g., sleep stages) or disease conditions (e.g., Alzheimer’s disease, minimal cognitive impairment).
Highlights
Resting-state functional magnetic resonance imaging has been increasingly applied to study activity and connectivity of the resting brain and involves the recording of the bloodoxygen-level-dependent (BOLD) signal without imposing a task (Biswal et al, 2010; X.-N. Zuo and Xing, 2014)
We found that the amplitude of rs-functional magnetic resonance imaging (fMRI) signals is slightly more precise than local and global connectivity models in order to detect resting brain changes during hunger and satiety with a classification accuracy of 81%
The amplitude of Resting-state functional magnetic resonance imaging (rs-fMRI) signals serves as a suitable basis for machine learning based classification of brain activity
Summary
Resting-state functional magnetic resonance imaging (rs-fMRI) has been increasingly applied to study activity and connectivity of the resting brain and involves the recording of the bloodoxygen-level-dependent (BOLD) signal without imposing a task (Biswal et al, 2010; X.-N. Zuo and Xing, 2014). Feature selection, which determines features that have to be included in Abbreviations: AAL, Automated-Anatomical-Labeling; AD, Alzheimer’s disease; APCUN, anterior precuneus; BMI, body mass index; BOLD, Blood-oxygen-level-dependent; CA, classification accuracy; CFS, cerebrospinal fluid; CM, confusion matrix; DARTEL, diffeomorphic anatomical registration through exponentiated Lie algebra; DC, degree of centrality; DPARSFA, data processing assistant for resting-state fMRI advanced edition; EPI, echo-planar imaging; ER, error rate; fALFF, fractional amplitude of low-frequency fluctuations; FC, function connectivity; fMRI, functional magnetic resonance imaging; FSL, FMRIB Software Library; GLM, general linear model; HC, healthy controls; ICA-AROMA, independent component analysis (ICA)-based strategy for automatic removal of motion artifacts; IFG, inferior frontal gyrus; KCC, Kendall’s coefficient concordance; LOC, lateral occipital cortex; LOOCV, h-out cross-validation; MCI, mild cognitive impairment; MLC, machine learning classifier; MNI, Montreal Neurological Institute; MVPA, multivariate voxel-pattern analysis; OLFC, olfactory cortex; ReHo, regional homogeneity; ROI, region of interest; rs-fMRI, resting-state functional magnetic resonance imaging; SFFS, sequential forward floating selection; SFS, sequential forward selection; SPM, statistical parametric mapping; SVM, support vector machine; TE, echo time; TR, repetition time
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