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Neural circuits and neuronal pools are two of the main structures found in the nervous system. Neural circuits are networks of neurons that work together to carry out a specific task or process. They consist of interconnected neurons and glial cells, which provide structural and metabolic support.
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Deep reinforcement learning guided graph neural networks for brain network analysis.

Xusheng Zhao1, Jia Wu2, Hao Peng3

  • 1Institute of Information Engineering, Chinese Academy of Sciences, Beijing, China; School of Cyber Security, University of Chinese Academy of Sciences, Beijing, China.

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Summary
This summary is machine-generated.

This study introduces BN-GNN, a novel framework using deep reinforcement learning to optimize graph neural network (GNN) architectures for brain network analysis. BN-GNN enhances understanding of brain structure and disease states by adapting GNN layers to individual brain networks.

Keywords:
Brain networkDeep reinforcement learningGraph neural networkNetwork representation learning

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Area of Science:

  • Neuroscience
  • Computer Science
  • Artificial Intelligence

Background:

  • Modern neuroimaging constructs human brains as connectomes, essential for understanding function and disease.
  • Graph neural networks (GNNs) show promise for brain network analysis via feature aggregation and global pooling.
  • Existing GNN methods use a fixed architecture, neglecting individual brain network complexities.

Purpose of the Study:

  • To propose a novel brain network representation framework, BN-GNN, to optimize GNN architectures for individual brain networks.
  • To address the limitation of fixed GNN layers in analyzing diverse brain network structures.
  • To enhance the performance of GNNs in brain network analysis tasks.

Main Methods:

  • Developed BN-GNN, a framework employing deep reinforcement learning (DRL).
  • Utilized DRL to automatically predict the optimal number of feature propagations (GNN layers) for each brain network.
  • Applied the framework to eight brain network disease analysis tasks.

Main Results:

  • BN-GNN successfully searches for optimal GNN architectures tailored to individual brain networks.
  • The framework demonstrates improved performance compared to traditional GNNs across eight disease analysis tasks.
  • Achieved enhanced upper bounds of performance in brain network analysis.

Conclusions:

  • BN-GNN offers a flexible and adaptive approach to brain network representation learning.
  • Optimizing GNN architecture through DRL significantly boosts performance in analyzing brain structure and disease.
  • This method advances the application of GNNs in neuroscience and brain disease research.