log-RRIM:通过局部到全局反应表征学习和交互建模进行产量预测。

ArXiv Pub Date : 2024-11-19
Xiao Hu, Ziqi Chen, Bo Peng, Daniel Adu-Ampratwum, Xia Ning
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引用次数: 0

摘要

准确预测化学反应产率对于优化有机合成至关重要,有可能减少用于实验的时间和资源。随着人工智能(AI)的兴起,人们对利用基于 AI 的方法在不进行体外实验的情况下加快产率预测越来越感兴趣。我们介绍了 log-RRIM,这是一种基于图变换器的创新框架,旨在预测化学反应产率。我们的方法实施了一种独特的从局部到全局的反应表征学习策略。这种方法首先捕捉详细的分子级信息,然后对分子间的相互作用进行建模和聚合,从而确保准确考虑不同大小的分子片段对产率的影响。log-RRIM 的另一个主要特点是整合了交叉注意机制,重点关注试剂和反应中心之间的相互作用。这一设计反映了化学反应中的一个基本原理:试剂在影响键的断裂和形成过程中起着至关重要的作用,而键的断裂和形成过程最终会影响反应产率。在我们的实验中,尤其是在中高产率反应中,log-RRIM 的表现优于现有方法,这证明了它作为预测器的可靠性。其先进的反应物-试剂相互作用建模和对小分子片段的敏感性,使其成为化学合成中反应规划和优化的重要工具。log-RRIM 的数据和代码可通过 https://github.com/ninglab/Yield_log_RRIM 访问。
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log-RRIM: Yield Prediction via Local-to-global Reaction Representation Learning and Interaction Modeling.

Accurate prediction of chemical reaction yields is crucial for optimizing organic synthesis, potentially reducing time and resources spent on experimentation. With the rise of artificial intelligence (AI), there is growing interest in leveraging AI-based methods to accelerate yield predictions without conducting in vitro experiments. We present log-RRIM, an innovative graph transformer-based framework designed for predicting chemical reaction yields. Our approach implements a unique local-to-global reaction representation learning strategy. This approach initially captures detailed molecule-level information and then models and aggregates intermolecular interactions, ensuring that the impact of varying-sizes molecular fragments on yield is accurately accounted for. Another key feature of log-RRIM is its integration of a cross-attention mechanism that focuses on the interplay between reagents and reaction centers. This design reflects a fundamental principle in chemical reactions: the crucial role of reagents in influencing bond-breaking and formation processes, which ultimately affect reaction yields. log-RRIM outperforms existing methods in our experiments, especially for medium to high-yielding reactions, proving its reliability as a predictor. Its advanced modeling of reactant-reagent interactions and sensitivity to small molecular fragments make it a valuable tool for reaction planning and optimization in chemical synthesis. The data and codes of log-RRIM are accessible through https://github.com/ninglab/YieldlogRRIM.

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