BrainGT: Multifunctional Brain Graph Transformer for Brain Disorder Diagnosis

Abstract

AbstractBrain networks play a crucial role in the diagnosis of brain disorders by enabling the identification of abnormal patterns and connections in brain activities. Previous studies exploit the Pearson’s correlation coefficient to construct functional brain networks from fMRI data and use graph learning to diagnose brain diseases. However, correlation-based brain networks are overly dense (often fully connected), which obscures meaningful connections and complicates subsequent analyses. This dense connectivity poses substantial performance challenges to traditional graph transformers, which are primarily designed for sparse graphs. Consequently, this results in a notable reduction in diagnostic accuracy. To address this challenging issue, we propose a multifunctional brain graph transformer model for brain disorders diagnosis, namely BrainGT, which is capable of constructing multifunctional brain networks rather than a dense brain network from fMRI data. It utilizes the fusion of self-attention and cross-attention mechanisms to learn important features within and across multiple functional brain networks. Classification (diagnosis) experiments conducted on three real fMRI datasets (i.e., ADNI, PPMI, and ABIDE) demonstrate the superiority of the proposed BrainGT over state-of-the-art methods.Impact StatementThe proposed BrainGT model represents a substantial advancement in computational neuroscience, offering a promising tool for more accurate and efficient diagnosis of brain disorders. By constructing multifunctional brain networks from fMRI data, BrainGT overcomes the limitations of traditional graph transformers and correlation-based brain networks. This innovation has profound implications across social, economic, and technological dimensions. Socially, BrainGT can enhance the quality of life for individuals with brain disorders by enabling more accurate diagnoses, leading to more effective treatments and better patient outcomes. Economically, BrainGT has the potential to reduce healthcare costs by streamlining the diagnostic process and potentially reducing the need for more expensive or invasive procedures. Technologically, BrainGT pushes the boundaries of AI and neuroscience, opening new avenues for research and development. It demonstrates the potential of AI to handle complex and dense data structures, with applications that could extend to other fields.