基于图神经网络的化学反应优劣评价

doi:10.16085/j.issn.1000-6613.2023-1415

摘要/Abstract

摘要：

化学反应的选择与设计在药物合成、材料合成领域中起到了关键性的作用，选择一条合适的化学反应能极大地优化反应条件，降低产品的合成时间，提升目标产物的合成产率。为能更好地分辨出化学反应的优劣程度，本文提出了一种用于评价化学反应优劣的图神经网络模型，通过采用基于反应前后原子映射关系构建的反应图描述符提取化学反应特征评估化学反应的优劣程度。首先，利用USPTO中反应数据建立包含反应映射关系的化学反应优劣数据集。然后，利用图神经网络方法建立起化学反应中各分子、原子特征与反应难易程度概率值的映射关系。最后，本文以阿司匹林合成反应为例，利用该模型对药品不同合成反应进行对比评估，并通过相关实验信息进行验证，证明当前评价指标的可行性与优越性。

关键词: 化学反应, 神经网络, 模型, 反应图描述符, 反应评价指标设计

Abstract:

Chemical reaction selection and design plays a key role in the field of drug synthesis and material synthesis. The selection of a proper chemical reaction could greatly optimize the synthesis reaction conditions, reduce time and improve synthesis yield of the product. In order to better distinguish the advantage degree of chemical reactions, a graphical neural network model was proposed to distinguish reaction superiority by using a reaction graph descriptor based on reaction atomic mapping relationships. Firstly, a reaction dataset for distinguishing the superiority of chemical reactions was established by using USPTO data. Then, the graphical neural network modeling method was used to establish the mapping relationship between the chemical reactions molecular and atomic features and the reaction superiority probability values. Finally, the aspirin different chemical synthesis reactions were taken as examples to prove and verify the feasibility and superiority of the reaction indicator by using the relevant experimental information.

Key words: chemical reaction, neural networks, model, reaction graph descriptor, reaction indicator design

中图分类号:

TQ460.3

徐晨阳, 都健, 张磊. 基于图神经网络的化学反应优劣评价[J]. 化工进展, 2023, 42(S1): 205-212.

XU Chenyang, DU Jian, ZHANG Lei. Chemical reaction evaluation based on graph network[J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 205-212.

图/表 15

参考文献 18

1	LI Baiqing, CHEN Hongming. Prediction of compound synthesis accessibility based on reaction knowledge graph[J]. Molecules, 2022, 27(3): 1039.
2	QIU Fayang. Strategic efficiency—The new thrust for synthetic organic chemists[J]. Canadian Journal of Chemistry, 2008, 86(9): 903-906.
3	Grzegorz SKORACZYŃSKI, KITLAS Mateusz, Błażej MIASOJEDOW, et al. Critical assessment of synthetic accessibility scores in computer-assisted synthesis planning[J]. Journal of Cheminformatics, 2023, 15(1): 1-9.
4	Milan VORŠILÁK, Michal KOLÁŘ, Ivan ČMELO, et al. SYBA: Bayesian estimation of synthetic accessibility of organic compounds[J]. Journal of Cheminformatics, 2020, 12(1): 1-13.
5	ITO Shun, BABA Yukino, ISOMURA Tetsu, et al. Synthetic accessibility assessment using auxiliary responses[J]. Expert Systems With Applications, 2020, 145: 113106.
6	COLEY C W, ROGERS L, GREEN W H, et al. SCScore: Synthetic complexity learned from a reaction corpus[J]. Journal of Chemical Information and Modeling, 2018, 58(2): 252-261.
7	YU Jiahui, WANG Jike, ZHAO Hong, et al. Organic compound synthetic accessibility prediction based on the graph attention mechanism[J]. Journal of Chemical Information and Modeling, 2022, 62(12): 2973-2986.
8	ERTL Peter, SCHUFFENHAUER Ansgar. Estimation of synthetic accessibility score of drug-like molecules based on molecular complexity and fragment contributions[J]. Journal of Cheminformatics, 2009, 1(1): 8.
9	ZHAO Yanan, LIU Xiaochen, LU Han, et al. An optimized deep convolutional neural network for yield prediction of Buchwald-Hartwig amination[J]. Chemical Physics, 2021, 550: 111296.
10	THAKKAR A, CHADIMOVÁ V, BJERRUM E J, et al. Retrosynthetic accessibility score (RAscore)–rapid machine learned synthesizability classification from AI driven retrosynthetic planning[J]. Chemical Science, 2021, 12(9): 3339-3349.
11	SHUI Zeren, KARYPIS George. Heterogeneous molecular graph neural networks for predicting molecule properties[C]//2020 IEEE International Conference on Data Mining (ICDM). November 17-20, 2020, Sorrento, Italy. IEEE, 2021: 492-500.
12	YOU Jiaxuan, LIU Bowen, YING Rex, et al. Graph convolutional policy network for goal-directed molecular graph generation[J/OL]. DOI: 10.48550/arXiv.1806.02473 .
13	NUGMANOV R I, MUKHAMETGALEEV R N, AKHMETSHIN T, et al. CGRtools: Python library for molecule, reaction, and condensed graph of reaction processing[J]. Journal of Chemical Information and Modeling, 2019, 59(6): 2516-2521.
14	TAVAKOLI Mohammadamin, SHMAKOV Alexander, CECCARELLI Francesco, et al. Rxn Hypergraph: A hypergraph attention model for chemical reaction representation[J/OL]. DOI: 10.48550/arXiv:2201. 01196 .
15	LOWE D M. Chemical reactions from US patents [P]. [2017-06-14]. .
16	LANDRUM G. Rdkit: Open-source chemoinformatics and machine learning. [EB/OL]. .
17	HU Weihua, LIU Bowen, GOMES Joseph, et al. Strategies for Pre-training Graph Neural Networks[C]//ICLR 2020, 2020.
18	(Reaxys Reaxys, accessed 9 May 2023) [EB/OL]. .

特征名称	特征维数	特征名称	特征维数
原子类型	72	原子芳香性	1×2
杂化类型	7×2	原子手性	4×2
原子电荷	8×2	原子是否在环上	6×2
原子连接数目	7×2	自由基数目	2×2
原子隐式化合价	7×2	H原子供体/受体	2×2
原子总化合价	7×2	原子酸性/碱性	2×2

特征名称	特征维数	特征名称	特征维数
原子类型	72	原子芳香性	1×2
杂化类型	7×2	原子手性	4×2
原子电荷	8×2	原子是否在环上	6×2
原子连接数目	7×2	自由基数目	2×2
原子隐式化合价	7×2	H原子供体/受体	2×2
原子总化合价	7×2	原子酸性/碱性	2×2

特征名称	特征维数	特征名称	特征维数
成键类型	4×2	是否为共轭键	1×2
是否为环上键	1×2	键的手性	4×2

特征名称	特征维数	特征名称	特征维数
成键类型	4×2	是否为共轭键	1×2
是否为环上键	1×2	键的手性	4×2

反应种类	优势反应	劣势反应
反应产率范围/%	90~100	0~50
反应时间范围/h	0.1~1.5	> 8
反应温度范围/℃	15~30	<-10；>100
特例	无	产率<15%，时间4~12h