新颖性
算法
化学空间
计算机科学
人工智能
生成模型
药物发现
计算生物学
机器学习
生成语法
生物信息学
生物
神学
哲学
作者
Mingyang Wang,Zhenhua Wu,Jike Wang,Gaoqi Weng,Yu Kang,Peichen Pan,Dan Li,Yafeng Deng,Xiaojun Yao,Zhitong Bing,Chang‐Yu Hsieh,Tingjun Hou
标识
DOI:10.1021/acs.jcim.3c01964
摘要
Deep learning-based de novo molecular design has recently gained significant attention. While numerous DL-based generative models have been successfully developed for designing novel compounds, the majority of the generated molecules lack sufficiently novel scaffolds or high drug-like profiles. The aforementioned issues may not be fully captured by commonly used metrics for the assessment of molecular generative models, such as novelty, diversity, and quantitative estimation of the drug-likeness score. To address these limitations, we proposed a genetic algorithm-guided generative model called GARel (genetic algorithm-based receptor-ligand interaction generator), a novel framework for training a DL-based generative model to produce drug-like molecules with novel scaffolds. To efficiently train the GARel model, we utilized dense net to update the parameters based on molecules with novel scaffolds and drug-like features. To demonstrate the capability of the GARel model, we used it to design inhibitors for three targets: AA2AR, EGFR, and SARS-Cov2. The results indicate that GARel-generated molecules feature more diverse and novel scaffolds and possess more desirable physicochemical properties and favorable docking scores. Compared with other generative models, GARel makes significant progress in balancing novelty and drug-likeness, providing a promising direction for the further development of DL-based de novo design methodology with potential impacts on drug discovery.
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