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Main Authors: Zhao, Zexing, Shi, Guangsi, Wu, Xiaopeng, Ren, Ruohua, Gao, Xiaojun, Li, Fuyi
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.02628
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author Zhao, Zexing
Shi, Guangsi
Wu, Xiaopeng
Ren, Ruohua
Gao, Xiaojun
Li, Fuyi
author_facet Zhao, Zexing
Shi, Guangsi
Wu, Xiaopeng
Ren, Ruohua
Gao, Xiaojun
Li, Fuyi
contents Molecular property prediction is a key component of AI-driven drug discovery and molecular characterization learning. Despite recent advances, existing methods still face challenges such as limited ability to generalize, and inadequate representation of learning from unlabeled data, especially for tasks specific to molecular structures. To address these limitations, we introduce DIG-Mol, a novel self-supervised graph neural network framework for molecular property prediction. This architecture leverages the power of contrast learning with dual interaction mechanisms and unique molecular graph enhancement strategies. DIG-Mol integrates a momentum distillation network with two interconnected networks to efficiently improve molecular characterization. The framework's ability to extract key information about molecular structure and higher-order semantics is supported by minimizing loss of contrast. We have established DIG-Mol's state-of-the-art performance through extensive experimental evaluation in a variety of molecular property prediction tasks. In addition to demonstrating superior transferability in a small number of learning scenarios, our visualizations highlight DIG-Mol's enhanced interpretability and representation capabilities. These findings confirm the effectiveness of our approach in overcoming challenges faced by traditional methods and mark a significant advance in molecular property prediction.
format Preprint
id arxiv_https___arxiv_org_abs_2405_02628
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Contrastive Dual-Interaction Graph Neural Network for Molecular Property Prediction
Zhao, Zexing
Shi, Guangsi
Wu, Xiaopeng
Ren, Ruohua
Gao, Xiaojun
Li, Fuyi
Machine Learning
Artificial Intelligence
Molecular property prediction is a key component of AI-driven drug discovery and molecular characterization learning. Despite recent advances, existing methods still face challenges such as limited ability to generalize, and inadequate representation of learning from unlabeled data, especially for tasks specific to molecular structures. To address these limitations, we introduce DIG-Mol, a novel self-supervised graph neural network framework for molecular property prediction. This architecture leverages the power of contrast learning with dual interaction mechanisms and unique molecular graph enhancement strategies. DIG-Mol integrates a momentum distillation network with two interconnected networks to efficiently improve molecular characterization. The framework's ability to extract key information about molecular structure and higher-order semantics is supported by minimizing loss of contrast. We have established DIG-Mol's state-of-the-art performance through extensive experimental evaluation in a variety of molecular property prediction tasks. In addition to demonstrating superior transferability in a small number of learning scenarios, our visualizations highlight DIG-Mol's enhanced interpretability and representation capabilities. These findings confirm the effectiveness of our approach in overcoming challenges faced by traditional methods and mark a significant advance in molecular property prediction.
title Contrastive Dual-Interaction Graph Neural Network for Molecular Property Prediction
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2405.02628