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Updated: Jun 22, 2025

Network Analysis of the Default Mode Network Using Functional Connectivity MRI in Temporal Lobe Epilepsy
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LCGNet: Local Sequential Feature Coupling Global Representation Learning for Functional Connectivity Network Analysis

Jie Zhou, Biao Jie, Zhengdong Wang

    IEEE Transactions on Medical Imaging
    |July 1, 2024
    PubMed
    Summary
    This summary is machine-generated.

    We introduce LCGNet, a novel deep learning model that combines convolutional neural networks (CNNs) and transformers to analyze functional connectivity networks (FCNs) from resting-state fMRI data for improved brain disease classification.

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    Area of Science:

    • Neuroimaging
    • Machine Learning
    • Brain Network Analysis

    Background:

    • Functional connectivity networks (FCNs) from resting-state fMRI are crucial for understanding brain diseases like Alzheimer's (AD) and ADHD.
    • Convolutional neural networks (CNNs) excel at local feature extraction but struggle with global temporal patterns in FCNs.
    • Transformers capture global temporal features effectively but often miss local network characteristics.

    Purpose of the Study:

    • To propose a novel network structure, LCGNet, that integrates CNNs and transformers for enhanced FCN representation learning.
    • To leverage both local and global topological information within brain networks for improved disease classification.
    • To address the limitations of existing methods in capturing comprehensive FCN features.

    Main Methods:

    • Construct dynamic FCNs using an overlapped sliding window approach from rs-fMRI data.
    • Employ a dual backbone architecture combining CNNs and transformers within sequential components (edge-to-vertex, vertex-to-network, network-to-temporality layers).
    • Develop LCGNet to couple local sequential features with global representations for comprehensive analysis.

    Main Results:

    • LCGNet demonstrated superior performance in classifying brain diseases compared to existing methods on real-world datasets.
    • The integrated approach effectively captures both local network properties and global temporal dynamics of FCNs.
    • Experimental validation on ADNI and ADHD-200 datasets confirmed the efficacy of LCGNet.

    Conclusions:

    • LCGNet offers a powerful new approach for brain disease classification by effectively integrating local and global FCN features.
    • The proposed architecture advances the application of deep learning in neuroimaging analysis.
    • This method holds promise for improving diagnostic accuracy and understanding of neurological disorders.