摘要278:人工智能加速药物发现

Weidong Xie, Xiaoyan Cheng, Zhengfang Ding, R. Deng, D. Gu
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引用次数: 0

摘要

药物发现是资源密集型的,通常需要10-20年的时间,成本从5亿美元到26亿美元不等。最近,人工智能(AI)在社会各领域的应用开始加速,制药行业也成为了领跑者。人工智能可以通过促进化合物的快速筛选和鉴定来加速药物发现并降低成本。我们开发了DM-AI药物发现平台,包括卷积神经网络、决策树算法、强化学习、生成对抗网络、大数据、知识图谱,以及基于结构和配体的高通量虚拟筛选,用于新药发现和开发。DM-AI优化了生物活性、毒性、理化性质。我们使用DM-AI发现了SHP2, PIM1, DNA-PK,涉及实体肿瘤和其他疾病的激酶靶点的有效抑制剂。我们开始在给定目标激酶抑制剂(阳性集)和非激酶目标分子(阴性集)的数据库上训练生物活性预测模型,然后预测现有数百万个数据集的活性,获得数千个结构的初始输出。然后,我们使用基于激酶抑制剂与靶蛋白复合物的虚拟化学空间的药效团奖励模型来评估这些结构。为了将我们的重点缩小到更小的分子组进行分析,我们对得分较高的化合物进行了过滤,以去除专利和应用分子,同时去除带有结构警报和反应基团的分子。在目标选择后的第7天,我们选择了数十个具有结构多样性的结构进行实验验证。在第28天,他们在酶激酶试验中进行了体外抑制活性测试,在一些目标模型中,活性化合物占65%。这说明了我们的DM-AI药物发现平台在成功、快速发现候选药物方面的实用性。引用格式:谢卫东,程兴,丁正芳,邓日强,顾大伟。人工智能加速药物发现[摘要]。见:美国癌症研究协会2021年年会论文集;2021年4月10日至15日和5月17日至21日。费城(PA): AACR;癌症杂志,2021;81(13 -增刊):278。
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Abstract 278: Artificial intelligence accelerate drug discovery
Drug discovery is resource intensive, and involves typical timelines of 10-20 years and costs that range from US$0.5 billion to US$2.6 billion. Artificial intelligence (AI) has recently started to gear-up its application in various sectors of the society and the pharmaceutical industry as a frontrunner beneficiary.Artificial intelligence can accelerate drug discovery and reduce costs by facilitating the rapid screening and identification of compounds. We have developed DM-AI drug discovery platform, including convolutional neural networks, decision treealgorithm, reinforcement learning, generative adversarial networks, big data, and knowledge graphs, along with structure and ligand-based high-throughput virtual screening , for new drug discovery and development. DM-AI optimizes biological activity,toxicity,physicochemical property. We used DM-AI to discover potent inhibitors of SHP2, PIM1, DNA-PK, kinases target implicated in solid tumor and other diseases.We started to train a biological activity prediction model on a database of the given target kinase inhibitors (positive set) and non-kinase targets molecules (negative set), and then predicted the activity of existing million data sets, obtained an initial output of thousands structures. We then evaluated these structures using a pharmacophore reward model on the basis of virtual chemical spaces of kinase inhibitors in complex with target protein. To narrow our focus to a smaller set of molecules for analysis, compounds with higher score were filtered to remove patents and applications molecules, also remove molecules bearing structural alerts and reactive groups.By day 7 after target selection, We had selected dozens structures with structural diversity for experimental validation. and by day 28, they were tested for in vitro inhibitory activity in an enzymatic kinase assay, active compounds accounted for up to 65% in some target models. This illustrates the utility of our DM-AI drug discovery platform for the successful, rapid discovery of drug candidates. Citation Format: Weidong Xie, Xing Cheng, Zhengfang Ding, Riqiang Deng, Dawei Gu. Artificial intelligence accelerate drug discovery [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 278.
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