Abstract
The functional screening of compounds is an important topic in chemistry and biomedicine that can uncover the essential properties of compounds and provide information concerning their correct use. In this study, we investigated the bioactive compounds reported in Selleckchem, which were assigned to 22 pathways. A computational method was proposed to identify the pathways of the bioactive compounds. Unlike most existing methods that only consider compound structural information, the proposed method adopted both the structural and interaction information from the compounds. The total accuracy achieved by our method was 61.79% based on jackknife analysis of a dataset of 1,832 bioactive compounds. Its performance was quite good compared with that of other machine learning algorithms (with total accuracies less than 46%). Finally, some of the false positives obtained by the method were analyzed to investigate the likelihood of compounds being annotated to new pathways.
Keywords: Bioactive compound, chemical-chemical interaction, chemical structure similarity, SMILES.
Combinatorial Chemistry & High Throughput Screening
Title:Prediction of Bioactive Compound Pathways Using Chemical Interaction and Structural Information
Volume: 19 Issue: 2
Author(s): Shiwen Cheng, Changming Zhu, Chen Chu, Tao Huang, Xiangyin Kong and LiuCun Zhu
Affiliation:
Keywords: Bioactive compound, chemical-chemical interaction, chemical structure similarity, SMILES.
Abstract: The functional screening of compounds is an important topic in chemistry and biomedicine that can uncover the essential properties of compounds and provide information concerning their correct use. In this study, we investigated the bioactive compounds reported in Selleckchem, which were assigned to 22 pathways. A computational method was proposed to identify the pathways of the bioactive compounds. Unlike most existing methods that only consider compound structural information, the proposed method adopted both the structural and interaction information from the compounds. The total accuracy achieved by our method was 61.79% based on jackknife analysis of a dataset of 1,832 bioactive compounds. Its performance was quite good compared with that of other machine learning algorithms (with total accuracies less than 46%). Finally, some of the false positives obtained by the method were analyzed to investigate the likelihood of compounds being annotated to new pathways.
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Cite this article as:
Cheng Shiwen, Zhu Changming, Chu Chen, Huang Tao, Kong Xiangyin and Zhu LiuCun, Prediction of Bioactive Compound Pathways Using Chemical Interaction and Structural Information, Combinatorial Chemistry & High Throughput Screening 2016; 19 (2) . https://dx.doi.org/10.2174/1386207319666151110123611
DOI https://dx.doi.org/10.2174/1386207319666151110123611 |
Print ISSN 1386-2073 |
Publisher Name Bentham Science Publisher |
Online ISSN 1875-5402 |
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