Adolescent Smoking Addiction Diagnosis Based on TI-GNN

Xu-Wen WANG; Da-Hua YU; Ting XUE; Xiao-Jiao LI; Zhen-Zhen MAI; Fang DONG; Yu-Xin MA; Juan WANG; Kai YUAN

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Adolescent Smoking Addiction Diagnosis Based on TI-GNN

VernacularTitle:基于新型图神经网络TI-GNN的青少年吸烟成瘾诊断
Author: Xu-Wen WANG ¹ ; Da-Hua YU ² ; Ting XUE ³ ; Xiao-Jiao LI ¹ ; Zhen-Zhen MAI ¹ ; Fang DONG ¹ ; Yu-Xin MA ¹ ; Juan WANG ¹ ; Kai YUAN ¹
Author Information

1. School of Digital and Intelligent Industry, Inner Mongolia University of Science and Technology, Baotou 014010, China
2. School of Automation and Electrical Engineering, Inner Mongolia University of Science and Technology, Baotou 014010, China
3. School of Science, Inner Mongolia University of Science and Technology, Baotou 014010, China
Publication Type:Journal Article
Keywords: spatial attention; Transformer; graph neural network; functional magnetic resonance imaging; classification; adolescent; smoking addiction
From: Progress in Biochemistry and Biophysics 2025;52(9):2393-2405
CountryChina
Language:Chinese
Abstract: ObjectiveTobacco-related diseases remain one of the leading preventable public health challenges worldwide and are among the primary causes of premature death. In recent years, accumulating evidence has supported the classification of nicotine addiction as a chronic brain disease, profoundly affecting both brain structure and function. Despite the urgency, effective diagnostic methods for smoking addiction remain lacking, posing significant challenges for early intervention and treatment. To address this issue and gain deeper insights into the neural mechanisms underlying nicotine dependence, this study proposes a novel graph neural network framework, termed TI-GNN. This model leverages functional magnetic resonance imaging (fMRI) data to identify complex and subtle abnormalities in brain connectivity patterns associated with smoking addiction. MethodsThe study utilizes fMRI data to construct functional connectivity matrices that represent interaction patterns among brain regions. These matrices are interpreted as graphs, where brain regions are nodes and the strength of functional connectivity between them serves as edges. The proposed TI-GNN model integrates a Transformer module to effectively capture global interactions across the entire brain network, enabling a comprehensive understanding of high-level connectivity patterns. Additionally, a spatial attention mechanism is employed to selectively focus on informative inter-regional connections while filtering out irrelevant or noisy features. This design enhances the model’s ability to learn meaningful neural representations crucial for classification tasks. A key innovation of TI-GNN lies in its built-in causal interpretation module, which aims to infer directional and potentially causal relationships among brain regions. This not only improves predictive performance but also enhances model interpretability—an essential attribute for clinical applications. The identification of causal links provides valuable insights into the neuropathological basis of addiction and contributes to the development of biologically plausible and trustworthy diagnostic tools. ResultsExperimental results demonstrate that the TI-GNN model achieves superior classification performance on the smoking addiction dataset, outperforming several state-of-the-art baseline models. Specifically, TI-GNN attains an accuracy of 0.91, an F1-score of 0.91, and a Matthews correlation coefficient (MCC) of 0.83, indicating strong robustness and reliability. Beyond performance metrics, TI-GNN identifies critical abnormal connectivity patterns in several brain regions implicated in addiction. Notably, it highlights dysregulations in the amygdala and the anterior cingulate cortex, consistent with prior clinical and neuroimaging findings. These regions are well known for their roles in emotional regulation, reward processing, and impulse control—functions that are frequently disrupted in nicotine dependence. ConclusionThe TI-GNN framework offers a powerful and interpretable tool for the objective diagnosis of smoking addiction. By integrating advanced graph learning techniques with causal inference capabilities, the model not only achieves high diagnostic accuracy but also elucidates the neurobiological underpinnings of addiction. The identification of specific abnormal brain networks and their causal interactions deepens our understanding of addiction pathophysiology and lays the groundwork for developing targeted intervention strategies and personalized treatment approaches in the future.