Your search keyword '"Yang, Zhi-Jiang"' showing total 2 results

1. PySmash: Python package and individual executable program for representative substructure generation and application.

Author

Yang, Zi-Yi, Yang, Zhi-Jiang, Zhao, Yue, Yin, Ming-Zhu, Lu, Ai-Ping, Chen, Xiang, Liu, Shao, Hou, Ting-Jun, and Cao, Dong-Sheng

Subjects

*PYTHON programming language, *QSAR models, *CHEMICAL libraries, *DOSAGE forms of drugs, *DATA integrity, *MACHINE learning

Abstract

Background Substructure screening is widely applied to evaluate the molecular potency and ADMET properties of compounds in drug discovery pipelines, and it can also be used to interpret QSAR models for the design of new compounds with desirable physicochemical and biological properties. With the continuous accumulation of more experimental data, data-driven computational systems which can derive representative substructures from large chemical libraries attract more attention. Therefore, the development of an integrated and convenient tool to generate and implement representative substructures is urgently needed. Results In this study, PySmash, a user-friendly and powerful tool to generate different types of representative substructures, was developed. The current version of PySmash provides both a Python package and an individual executable program, which achieves ease of operation and pipeline integration. Three types of substructure generation algorithms, including circular, path-based and functional group-based algorithms, are provided. Users can conveniently customize their own requirements for substructure size, accuracy and coverage, statistical significance and parallel computation during execution. Besides, PySmash provides the function for external data screening. Conclusion PySmash, a user-friendly and integrated tool for the automatic generation and implementation of representative substructures, is presented. Three screening examples, including toxicophore derivation, privileged motif detection and the integration of substructures with machine learning (ML) models, are provided to illustrate the utility of PySmash in safety profile evaluation, therapeutic activity exploration and molecular optimization, respectively. Its executable program and Python package are available at https://github.com/kotori-y/pySmash. [ABSTRACT FROM AUTHOR]

Published

2021

2. QSAR-assisted-MMPA to expand chemical transformation space for lead optimization.

Author

Fu, Li, Yang, Zi-Yi, Yang, Zhi-Jiang, Yin, Ming-Zhu, Lu, Ai-Ping, Chen, Xiang, Liu, Shao, Hou, Ting-Jun, and Cao, Dong-Sheng

Subjects

CHEMICAL amplification, PHARMACEUTICAL chemistry, STRUCTURE-activity relationships, PREDICTION models

Abstract

Matched molecular pairs analysis (MMPA) has become a powerful tool for automatically and systematically identifying medicinal chemistry transformations from compound/property datasets. However, accurate determination of matched molecular pair (MMP) transformations largely depend on the size and quality of existing experimental data. Lack of high-quality experimental data heavily hampers the extraction of more effective medicinal chemistry knowledge. Here, we developed a new strategy called quantitative structure–activity relationship (QSAR)-assisted-MMPA to expand the number of chemical transformations and took the logD7.4 property endpoint as an example to demonstrate the reliability of the new method. A reliable logD7.4 consensus prediction model was firstly established, and its applicability domain was strictly assessed. By applying the reliable logD7.4 prediction model to screen two chemical databases, we obtained more high-quality logD7.4 data by defining a strict applicability domain threshold. Then, MMPA was performed on the predicted data and experimental data to derive more chemical rules. To validate the reliability of the chemical rules, we compared the magnitude and directionality of the property changes of the predicted rules with those of the measured rules. Then, we compared the novel chemical rules generated by our proposed approach with the published chemical rules, and found that the magnitude and directionality of the property changes were consistent, indicating that the proposed QSAR-assisted-MMPA approach has the potential to enrich the collection of rule types or even identify completely novel rules. Finally, we found that the number of the MMP rules derived from the experimental data could be amplified by the predicted data, which is helpful for us to analyze the medicinal chemical rules in local chemical environment. In summary, the proposed QSAR-assisted-MMPA approach could be regarded as a very promising strategy to expand the chemical transformation space for lead optimization, especially when no enough experimental data can support MMPA. [ABSTRACT FROM AUTHOR]

Published

2021