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Main Authors: Feng, Shikun, Zheng, Jiaxin, Jia, Yinjun, Huang, Yanwen, Zhou, Fengfeng, Ma, Wei-Ying, Lan, Yanyan
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.17797
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author Feng, Shikun
Zheng, Jiaxin
Jia, Yinjun
Huang, Yanwen
Zhou, Fengfeng
Ma, Wei-Ying
Lan, Yanyan
author_facet Feng, Shikun
Zheng, Jiaxin
Jia, Yinjun
Huang, Yanwen
Zhou, Fengfeng
Ma, Wei-Ying
Lan, Yanyan
contents Molecular representation learning is pivotal for various molecular property prediction tasks related to drug discovery. Robust and accurate benchmarks are essential for refining and validating current methods. Existing molecular property benchmarks derived from wet experiments, however, face limitations such as data volume constraints, unbalanced label distribution, and noisy labels. To address these issues, we construct a large-scale and precise molecular representation dataset of approximately 140,000 small molecules, meticulously designed to capture an extensive array of chemical, physical, and biological properties, derived through a robust computational ligand-target binding analysis pipeline. We conduct extensive experiments on various deep learning models, demonstrating that our dataset offers significant physicochemical interpretability to guide model development and design. Notably, the dataset's properties are linked to binding affinity metrics, providing additional insights into model performance in drug-target interaction tasks. We believe this dataset will serve as a more accurate and reliable benchmark for molecular representation learning, thereby expediting progress in the field of artificial intelligence-driven drug discovery.
format Preprint
id arxiv_https___arxiv_org_abs_2406_17797
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle MoleculeCLA: Rethinking Molecular Benchmark via Computational Ligand-Target Binding Analysis
Feng, Shikun
Zheng, Jiaxin
Jia, Yinjun
Huang, Yanwen
Zhou, Fengfeng
Ma, Wei-Ying
Lan, Yanyan
Chemical Physics
Artificial Intelligence
Machine Learning
Molecular representation learning is pivotal for various molecular property prediction tasks related to drug discovery. Robust and accurate benchmarks are essential for refining and validating current methods. Existing molecular property benchmarks derived from wet experiments, however, face limitations such as data volume constraints, unbalanced label distribution, and noisy labels. To address these issues, we construct a large-scale and precise molecular representation dataset of approximately 140,000 small molecules, meticulously designed to capture an extensive array of chemical, physical, and biological properties, derived through a robust computational ligand-target binding analysis pipeline. We conduct extensive experiments on various deep learning models, demonstrating that our dataset offers significant physicochemical interpretability to guide model development and design. Notably, the dataset's properties are linked to binding affinity metrics, providing additional insights into model performance in drug-target interaction tasks. We believe this dataset will serve as a more accurate and reliable benchmark for molecular representation learning, thereby expediting progress in the field of artificial intelligence-driven drug discovery.
title MoleculeCLA: Rethinking Molecular Benchmark via Computational Ligand-Target Binding Analysis
topic Chemical Physics
Artificial Intelligence
Machine Learning
url https://arxiv.org/abs/2406.17797