Your search keyword '"Niu, Zhangming"' showing total 4 results

1. PharmaBench: Enhancing ADMET benchmarks with large language models.

Author

Niu, Zhangming, Xiao, Xianglu, Wu, Wenfan, Cai, Qiwei, Jiang, Yinghui, Jin, Wangzhen, Wang, Minhao, Yang, Guojian, Kong, Lingkang, Jin, Xurui, Yang, Guang, and Chen, Hongming

Subjects

LANGUAGE models, DRUG discovery, DOSAGE forms of drugs, ELECTRONIC data processing, DRUG development

Abstract

Accurately predicting ADMET (Absorption, Distribution, Metabolism, Excretion, and Toxicity) properties early in drug development is essential for selecting compounds with optimal pharmacokinetics and minimal toxicity. Existing ADMET-related benchmark sets are limited in utility due to their small dataset sizes and the lack of representation of compounds used in drug discovery projects. These shortcomings hinder their application in model building for drug discovery. To address this issue, we propose a multi-agent data mining system based on Large Language Models that effectively identifies experimental conditions within 14,401 bioassays. This approach facilitates merging entries from different sources, culminating in the creation of PharmaBench. Additionally, we have developed a data processing workflow to integrate data from various sources, resulting in 156,618 raw entries. Through this workflow, we constructed PharmaBench, a comprehensive benchmark set for ADMET properties, which comprises eleven ADMET datasets and 52,482 entries. This benchmark set is designed to serve as an open-source dataset for the development of AI models relevant to drug discovery projects. [ABSTRACT FROM AUTHOR]

Published

2024

2. Automated molecular structure segmentation from documents using ChemSAM.

Author

Tang, Bowen, Niu, Zhangming, Wang, Xiaofeng, Huang, Junjie, Ma, Chao, Peng, Jing, Jiang, Yinghui, Ge, Ruiquan, Hu, Hongyu, Lin, Luhao, and Yang, Guang

Subjects

*MOLECULAR structure, *TRANSFORMER models, *CHEMICAL structure, *DEEP learning, *PERIODICAL articles

Abstract

Chemical structure segmentation constitutes a pivotal task in cheminformatics, involving the extraction and abstraction of structural information of chemical compounds from text-based sources, including patents and scientific articles. This study introduces a deep learning approach to chemical structure segmentation, employing a Vision Transformer (ViT) to discern the structural patterns of chemical compounds from their graphical representations. The Chemistry-Segment Anything Model (ChemSAM) achieves state-of-the-art results on publicly available benchmark datasets and real-world tasks, underscoring its effectiveness in accurately segmenting chemical structures from text-based sources. Moreover, this deep learning-based approach obviates the need for handcrafted features and demonstrates robustness against variations in image quality and style. During the detection phase, a ViT-based encoder-decoder model is used to identify and locate chemical structure depictions on the input page. This model generates masks to ascertain whether each pixel belongs to a chemical structure, thereby offering a pixel-level classification and indicating the presence or absence of chemical structures at each position. Subsequently, the generated masks are clustered based on their connectivity, and each mask cluster is updated to encapsulate a single structure in the post-processing workflow. This two-step process facilitates the effective automatic extraction of chemical structure depictions from documents. By utilizing the deep learning approach described herein, it is demonstrated that effective performance on low-resolution and densely arranged molecular structural layouts in journal articles and patents is achievable. [ABSTRACT FROM AUTHOR]

Published

2024

3. Pharmacophoric-constrained heterogeneous graph transformer model for molecular property prediction.

Author

Jiang, Yinghui, Jin, Shuting, Jin, Xurui, Xiao, Xianglu, Wu, Wenfan, Liu, Xiangrong, Zhang, Qiang, Zeng, Xiangxiang, Yang, Guang, and Niu, Zhangming

Subjects

MOLECULAR graphs, DRUG discovery, REPRESENTATIONS of graphs, CHEMICAL reactions, CHEMICAL structure

Abstract

Informative representation of molecules is a crucial prerequisite in AI-driven drug design and discovery. Pharmacophore information including functional groups and chemical reactions can indicate molecular properties, which have not been fully exploited by prior atom-based molecular graph representation. To obtain a more informative representation of molecules for better molecule property prediction, we propose the Pharmacophoric-constrained Heterogeneous Graph Transformer (PharmHGT). We design a pharmacophoric-constrained multi-views molecular representation graph, enabling PharmHGT to extract vital chemical information from functional substructures and chemical reactions. With a carefully designed pharmacophoric-constrained multi-view molecular representation graph, PharmHGT can learn more chemical information from molecular functional substructures and chemical reaction information. Extensive downstream experiments prove that PharmHGT achieves remarkably superior performance over the state-of-the-art models the performance of our model is up to 1.55% in ROC-AUC and 0.272 in RMSE higher than the best baseline model) on molecular properties prediction. The ablation study and case study show that our proposed molecular graph representation method and heterogeneous graph transformer model can better capture the pharmacophoric structure and chemical information features. Further visualization studies also indicated a better representation capacity achieved by our model. Informative molecular representation is a vital prerequisite in artificial intelligence-driven de novo drug discovery, however, mapping the pharmacophoric information is underexploited by the atom-level based molecular graph representation. Here, the authors design a multi-level based Pharmacophoric-constrained heterogeneous graph transformer (PharmHGT) to better capture the pharmacophore structure and chemical information. [ABSTRACT FROM AUTHOR]

Published

2023

4. Amelioration of Alzheimer's disease pathology by mitophagy inducers identified via machine learning and a cross-species workflow.

Author

Xie, Chenglong, Zhuang, Xu-Xu, Niu, Zhangming, Ai, Ruixue, Lautrup, Sofie, Zheng, Shuangjia, Jiang, Yinghui, Han, Ruiyu, Gupta, Tanima Sen, Cao, Shuqin, Lagartos-Donate, Maria Jose, Cai, Cui-Zan, Xie, Li-Ming, Caponio, Domenica, Wang, Wen-Wen, Schmauck-Medina, Tomas, Zhang, Jianying, Wang, He-ling, Lou, Guofeng, and Xiao, Xianglu

Published

2022