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Autori principali: Guo, Peijin, Li, Minghui, Pan, Hewen, Chen, Bowen, Wu, Yang, Guo, Zikang, Zhang, Leo Yu, Hu, Shengshan, Hu, Shengqing
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2506.00936
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author Guo, Peijin
Li, Minghui
Pan, Hewen
Chen, Bowen
Wu, Yang
Guo, Zikang
Zhang, Leo Yu
Hu, Shengshan
Hu, Shengqing
author_facet Guo, Peijin
Li, Minghui
Pan, Hewen
Chen, Bowen
Wu, Yang
Guo, Zikang
Zhang, Leo Yu
Hu, Shengshan
Hu, Shengqing
contents Accurate prediction of molecular metabolic stability (MS) is critical for drug research and development but remains challenging due to the complex interplay of molecular interactions. Despite recent advances in graph neural networks (GNNs) for MS prediction, current approaches face two critical limitations: (1) incomplete molecular modeling due to atom-centric message-passing mechanisms that disregard bond-level topological features, and (2) prediction frameworks that lack reliable uncertainty quantification. To address these challenges, we propose TrustworthyMS, a novel contrastive learning framework designed for uncertainty-aware metabolic stability prediction. First, a molecular graph topology remapping mechanism synchronizes atom-bond interactions through edge-induced feature propagation, capturing both localized electronic effects and global conformational constraints. Second, contrastive topology-bond alignment enforces consistency between molecular topology views and bond patterns via feature alignment, enhancing representation robustness. Third, uncertainty modeling through Beta-Binomial uncertainty quantification enables simultaneous prediction and confidence calibration under epistemic uncertainty. Through extensive experiments, our results demonstrate that TrustworthyMS outperforms current state-of-the-art methods in terms of predictive performance.
format Preprint
id arxiv_https___arxiv_org_abs_2506_00936
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Uncertainty-Aware Metabolic Stability Prediction with Dual-View Contrastive Learning
Guo, Peijin
Li, Minghui
Pan, Hewen
Chen, Bowen
Wu, Yang
Guo, Zikang
Zhang, Leo Yu
Hu, Shengshan
Hu, Shengqing
Machine Learning
Artificial Intelligence
Quantitative Methods
Accurate prediction of molecular metabolic stability (MS) is critical for drug research and development but remains challenging due to the complex interplay of molecular interactions. Despite recent advances in graph neural networks (GNNs) for MS prediction, current approaches face two critical limitations: (1) incomplete molecular modeling due to atom-centric message-passing mechanisms that disregard bond-level topological features, and (2) prediction frameworks that lack reliable uncertainty quantification. To address these challenges, we propose TrustworthyMS, a novel contrastive learning framework designed for uncertainty-aware metabolic stability prediction. First, a molecular graph topology remapping mechanism synchronizes atom-bond interactions through edge-induced feature propagation, capturing both localized electronic effects and global conformational constraints. Second, contrastive topology-bond alignment enforces consistency between molecular topology views and bond patterns via feature alignment, enhancing representation robustness. Third, uncertainty modeling through Beta-Binomial uncertainty quantification enables simultaneous prediction and confidence calibration under epistemic uncertainty. Through extensive experiments, our results demonstrate that TrustworthyMS outperforms current state-of-the-art methods in terms of predictive performance.
title Uncertainty-Aware Metabolic Stability Prediction with Dual-View Contrastive Learning
topic Machine Learning
Artificial Intelligence
Quantitative Methods
url https://arxiv.org/abs/2506.00936