An Adaptively Weighted Averaging Method for Regional Time Series Extraction of fMRI-based Brain Decoding

TL;DR

This paper introduces an adaptively weighted averaging method using neural networks to improve the extraction of regional time series from fMRI data, enhancing brain decoding accuracy and interpretability.

Contribution

It proposes a novel neural network-based adaptive averaging technique for fMRI time series extraction, outperforming traditional methods in decoding accuracy and interpretability.

Findings

Up to 5% increase in decoding accuracy.

Enhanced separability among cognitive states in manifold learning.

Identifies relevant brain regions for different cognitive states.

Abstract

Brain decoding that classifies cognitive states using the functional fluctuations of the brain can provide insightful information for understanding the brain mechanisms of cognitive functions. Among the common procedures of decoding the brain cognitive states with functional magnetic resonance imaging (fMRI), extracting the time series of each brain region after brain parcellation traditionally averages across the voxels within a brain region. This neglects the spatial information among the voxels and the requirement of extracting information for the downstream tasks. In this study, we propose to use a fully connected neural network that is jointly trained with the brain decoder to perform an adaptively weighted average across the voxels within each brain region. We perform extensive evaluations by cognitive state decoding, manifold learning, and interpretability analysis on the Human Connectome Project (HCP) dataset. The performance comparison of the cognitive state decoding presents an accuracy increase of up to 5\% and stable accuracy improvement under different time window sizes, resampling sizes, and training data sizes. The results of manifold learning show that our method presents a considerable separability among cognitive states and basically excludes subject-specific information. The interpretability analysis shows that our method can identify reasonable brain regions corresponding to each cognitive state. Our study would aid the improvement of the basic pipeline of fMRI processing.