Your search keyword '"Meimei Chen"' showing total 7 results

1. Fast Identification of Adverse Drug Reactions (ADRs) of Digestive and Nervous Systems of Organic Drugs by In Silico Models

Author

Meimei Chen, Zhaoyang Yang, Yuxing Gao, and Candong Li

Subjects

adverse drug reactions, drug, QSAR model, SVM, LDA, DL, Organic chemistry, QD241-441

Abstract

This study aimed to discover concurrences of adverse drug reactions (ADRs) and derive models of the most frequent items of ADRs based on the SIDER database, which included 1430 marketed drugs and 5868 ADRs. First, common ADRs of organic drugs were manually reclassified according to side effects in the human system and followed by an association rule analysis, which found ADRs of digestive and nervous systems often occurred at the same time with a good association rule. Then, three algorithms, linear discriminant analysis (LDA), support vector machine (SVM) and deep learning, were used to derive models of ADRs of digestive and nervous systems based on 497 organic monomer drugs and to identify key structural features in defining these ADRs. The statistical results indicated that these kinds of QSAR models were good tools for screening ADRs of digestive and nervous systems, which gave the ROC AUC values of 81.5%, 98.9%, 91.5%, 69.5%, 78.4% and 78.8%, respectively. Then, these models were applied to investigate ADRs of 1536 organic compounds with four phase and zero rule-of-five (RO5) violations from the ChEMBL database. Based on the consensus ADRs’ predictions of models, 58.1% and 42.6% of compounds were predicted to cause these two ADRs, respectively, indicating the significance of initial assessment of ADRs in early drug discovery.

Published

2021

2. Exploration in the Mechanism of Action of Licorice by Network Pharmacology

Author

Meimei Chen, Jingru Zhu, Jie Kang, Xinmei Lai, Yuxing Gao, Huijuan Gan, and Fafu Yang

Subjects

licorice, food additive, network analysis, target identification, KEGG pathway analysis, Organic chemistry, QD241-441

Abstract

Licorice is a popular sweetener and a thirst quencher in many food products particularly in Europe and the Middle East and also one of the oldest and most frequently used herbs in traditional Chinese medicine. As a wide application of food additive, it is necessary to clarify bioactive chemical ingredients and the mechanism of action of licorice. In this study, a network pharmacology approach that integrated drug-likeness evaluation, structural similarity analysis, target identification, network analysis, and KEGG pathway analysis was established to elucidate the potential molecular mechanism of licorice. First, we collected and evaluated structural information of 282 compounds in licorice and found 181 compounds that met oral drug rules. Then, structural similarity analysis with known ligands of targets in the ChEMBL database (similarity threshold = 0.8) was applied to the initial target identification, which found 63 compounds in licorice had 86 multi-targets. Further, molecular docking was performed to study their binding modes and interactions, which screened out 49 targets. Finally, 17 enriched KEGG pathways (p < 0.01) of licorice were obtained, exhibiting a variety of biological activities. Overall, this study provided a feasible and accurate approach to explore the safe and effective application of licorice as a food additive and herb medicine.

Published

2019

3. Identfication of Potent LXRβ-Selective Agonists without LXRα Activation by In Silico Approaches

Author

Meimei Chen, Fafu Yang, Jie Kang, Huijuan Gan, Xuemei Yang, Xinmei Lai, and Yuxing Gao

Subjects

LXRβ-selective agonists, QSAR modeling, molecular docking, Kohonen, Organic chemistry, QD241-441

Abstract

Activating Liver X receptors (LXRs) represents a promising therapeutic option for dyslipidemia. However, activating LXRα may cause undesired lipogenic effects. Discovery of highly LXRβ-selective agonists without LXRα activation were indispensable for dyslipidemia. In this study, in silico approaches were applied to develop highly potent LXRβ-selective agonists based on a series of newly reported 3-(4-(2-propylphenoxy)butyl)imidazolidine-2,4-dione-based LXRα/β dual agonists. Initially, Kohonen and stepwise multiple linear regression SW-MLR were performed to construct models for LXRβ agonists and LXRα agonists based on the structural characteristics of LXRα/β dual agonists, respectively. The obtained LXRβ agonist model gave a good predictive ability (R2train = 0.837, R2test = 0.843, Q2LOO = 0.715), and the LXRα agonist model produced even better predictive ability (R2train = 0.968, R2test = 0.914, Q2LOO = 0.895). Also, the two QSAR models were independent and can well distinguish LXRβ and LXRα activity. Then, compounds in the ZINC database met the lower limit of structural similarity of 0.7, compared to the 3-(4-(2-propylphenoxy)butyl)imidazolidine-2,4-dione scaffold subjected to our QSAR models, which resulted in the discovery of ZINC55084484 with an LXRβ prediction value of pEC50 equal to 7.343 and LXRα prediction value of pEC50 equal to −1.901. Consequently, nine newly designed compounds were proposed as highly LXRβ-selective agonists based on ZINC55084484 and molecular docking, of which LXRβ prediction values almost exceeded 8 and LXRα prediction values were below 0.

Published

2018

4. Multi-Layer Identification of Highly-Potent ABCA1 Up-Regulators Targeting LXRβ Using Multiple QSAR Modeling, Structural Similarity Analysis, and Molecular Docking

Author

Meimei Chen, Fafu Yang, Jie Kang, Xuemei Yang, Xinmei Lai, and Yuxing Gao

Subjects

ABCA1, QSAR, molecular modeling, similarity analysis, molecular docking, LXRβ, Organic chemistry, QD241-441

Abstract

In this study, in silico approaches, including multiple QSAR modeling, structural similarity analysis, and molecular docking, were applied to develop QSAR classification models as a fast screening tool for identifying highly-potent ABCA1 up-regulators targeting LXRβ based on a series of new flavonoids. Initially, four modeling approaches, including linear discriminant analysis, support vector machine, radial basis function neural network, and classification and regression trees, were applied to construct different QSAR classification models. The statistics results indicated that these four kinds of QSAR models were powerful tools for screening highly potent ABCA1 up-regulators. Then, a consensus QSAR model was developed by combining the predictions from these four models. To discover new ABCA1 up-regulators at maximum accuracy, the compounds in the ZINC database that fulfilled the requirement of structural similarity of 0.7 compared to known potent ABCA1 up-regulator were subjected to the consensus QSAR model, which led to the discovery of 50 compounds. Finally, they were docked into the LXRβ binding site to understand their role in up-regulating ABCA1 expression. The excellent binding modes and docking scores of 10 hit compounds suggested they were highly-potent ABCA1 up-regulators targeting LXRβ. Overall, this study provided an effective strategy to discover highly potent ABCA1 up-regulators.

Published

2016

5. Fast Identification of Adverse Drug Reactions (ADRs) of Digestive and Nervous Systems of Organic Drugs by In Silico Models

Author

Yuxing Gao, Candong Li, Zhaoyang Yang, and Meimei Chen

Subjects

Drug, Quantitative structure–activity relationship, Databases, Factual, Drug-Related Side Effects and Adverse Reactions, LDA, Digestive System Diseases, SVM, media_common.quotation_subject, In silico, QSAR model, Pharmaceutical Science, Bioinformatics, Article, Analytical Chemistry, lcsh:QD241-441, 03 medical and health sciences, 0404 agricultural biotechnology, lcsh:Organic chemistry, DL, Drug Discovery, Humans, Medicine, Computer Simulation, Drug reaction, Physical and Theoretical Chemistry, 030304 developmental biology, media_common, adverse drug reactions, 0303 health sciences, business.industry, Organic Chemistry, drug, 04 agricultural and veterinary sciences, chEMBL, 040401 food science, Human system, Pharmaceutical Preparations, Chemistry (miscellaneous), Molecular Medicine, Nervous System Diseases, business, Algorithms

Abstract

This study aimed to discover concurrences of adverse drug reactions (ADRs) and derive models of the most frequent items of ADRs based on the SIDER database, which included 1430 marketed drugs and 5868 ADRs. First, common ADRs of organic drugs were manually reclassified according to side effects in the human system and followed by an association rule analysis, which found ADRs of digestive and nervous systems often occurred at the same time with a good association rule. Then, three algorithms, linear discriminant analysis (LDA), support vector machine (SVM) and deep learning, were used to derive models of ADRs of digestive and nervous systems based on 497 organic monomer drugs and to identify key structural features in defining these ADRs. The statistical results indicated that these kinds of QSAR models were good tools for screening ADRs of digestive and nervous systems, which gave the ROC AUC values of 81.5%, 98.9%, 91.5%, 69.5%, 78.4% and 78.8%, respectively. Then, these models were applied to investigate ADRs of 1536 organic compounds with four phase and zero rule-of-five (RO5) violations from the ChEMBL database. Based on the consensus ADRs’ predictions of models, 58.1% and 42.6% of compounds were predicted to cause these two ADRs, respectively, indicating the significance of initial assessment of ADRs in early drug discovery.

Published

2021

6. Identfication of Potent LXRβ-Selective Agonists without LXRα Activation by In Silico Approaches

Author

Xinmei Lai, Huijuan Gan, Jie Kang, Xuemei Yang, Meimei Chen, Fafu Yang, and Yuxing Gao

Subjects

0301 basic medicine, Agonist, LXRβ-selective agonists, Quantitative structure–activity relationship, Structural similarity, medicine.drug_class, In silico, Drug Evaluation, Preclinical, Pharmaceutical Science, Quantitative Structure-Activity Relationship, Pharmacology, digestive system, Lower limit, Article, Analytical Chemistry, lcsh:QD241-441, 03 medical and health sciences, QSAR modeling, lcsh:Organic chemistry, Drug Discovery, medicine, polycyclic compounds, Animals, Computer Simulation, Physical and Theoretical Chemistry, Liver X receptor, Kohonen, Liver X Receptors, Chemistry, Organic Chemistry, food and beverages, nutritional and metabolic diseases, molecular docking, Zinc database, Molecular Docking Simulation, 030104 developmental biology, Chemistry (miscellaneous), Molecular Medicine, lipids (amino acids, peptides, and proteins)

Abstract

Activating Liver X receptors (LXRs) represents a promising therapeutic option for dyslipidemia. However, activating LXR&alpha, may cause undesired lipogenic effects. Discovery of highly LXR&beta, selective agonists without LXR&alpha, activation were indispensable for dyslipidemia. In this study, in silico approaches were applied to develop highly potent LXR&beta, selective agonists based on a series of newly reported 3-(4-(2-propylphenoxy)butyl)imidazolidine-2,4-dione-based LXR&alpha, /&beta, dual agonists. Initially, Kohonen and stepwise multiple linear regression SW-MLR were performed to construct models for LXR&beta, agonists and LXR&alpha, agonists based on the structural characteristics of LXR&alpha, dual agonists, respectively. The obtained LXR&beta, agonist model gave a good predictive ability (R2train = 0.837, R2test = 0.843, Q2LOO = 0.715), and the LXR&alpha, agonist model produced even better predictive ability (R2train = 0.968, R2test = 0.914, Q2LOO = 0.895). Also, the two QSAR models were independent and can well distinguish LXR&beta, and LXR&alpha, activity. Then, compounds in the ZINC database met the lower limit of structural similarity of 0.7, compared to the 3-(4-(2-propylphenoxy)butyl)imidazolidine-2,4-dione scaffold subjected to our QSAR models, which resulted in the discovery of ZINC55084484 with an LXR&beta, prediction value of pEC50 equal to 7.343 and LXR&alpha, prediction value of pEC50 equal to &minus, 1.901. Consequently, nine newly designed compounds were proposed as highly LXR&beta, selective agonists based on ZINC55084484 and molecular docking, of which LXR&beta, prediction values almost exceeded 8 and LXR&alpha, prediction values were below 0.

Published

2018

7. Multi-Layer Identification of Highly-Potent ABCA1 Up-Regulators Targeting LXRβ Using Multiple QSAR Modeling, Structural Similarity Analysis, and Molecular Docking

Author

Yuxing Gao, Fafu Yang, Meimei Chen, Xinmei Lai, Jie Kang, and Xuemei Yang

Subjects

Models, Molecular, 0301 basic medicine, LXRβ, Quantitative structure–activity relationship, Support Vector Machine, Molecular model, Structural similarity, In silico, Quantitative Structure-Activity Relationship, Pharmaceutical Science, ABCA1, Computational biology, Biology, Article, Analytical Chemistry, lcsh:QD241-441, 03 medical and health sciences, lcsh:Organic chemistry, Drug Discovery, QSAR, molecular modeling, similarity analysis, molecular docking, Humans, Computer Simulation, Physical and Theoretical Chemistry, Multi layer, Liver X Receptors, Flavonoids, Binding Sites, Cholesterol, HDL, Organic Chemistry, Atherosclerosis, Linear discriminant analysis, Combinatorial chemistry, Molecular Docking Simulation, Support vector machine, 030104 developmental biology, Chemistry (miscellaneous), Docking (molecular), Drug Design, Molecular Medicine, Neural Networks, Computer, Databases, Chemical, ATP Binding Cassette Transporter 1

Abstract

In this study, in silico approaches, including multiple QSAR modeling, structural similarity analysis, and molecular docking, were applied to develop QSAR classification models as a fast screening tool for identifying highly-potent ABCA1 up-regulators targeting LXRβ based on a series of new flavonoids. Initially, four modeling approaches, including linear discriminant analysis, support vector machine, radial basis function neural network, and classification and regression trees, were applied to construct different QSAR classification models. The statistics results indicated that these four kinds of QSAR models were powerful tools for screening highly potent ABCA1 up-regulators. Then, a consensus QSAR model was developed by combining the predictions from these four models. To discover new ABCA1 up-regulators at maximum accuracy, the compounds in the ZINC database that fulfilled the requirement of structural similarity of 0.7 compared to known potent ABCA1 up-regulator were subjected to the consensus QSAR model, which led to the discovery of 50 compounds. Finally, they were docked into the LXRβ binding site to understand their role in up-regulating ABCA1 expression. The excellent binding modes and docking scores of 10 hit compounds suggested they were highly-potent ABCA1 up-regulators targeting LXRβ. Overall, this study provided an effective strategy to discover highly potent ABCA1 up-regulators.

Published

2016