Your search keyword '"Liangxu Xie"' showing total 18 results

1. Harnessing Multiple Level Features to Improve Segmentation Performance of Deep Neural Network: A Case Study in Magnetic Resonance Imaging of Nasopharyngeal Cancer

Author

Rongzhi Mao, Liangxu Xie, Xiaohua Lu, Jialu Pei, Xiaojun Xu, and Shan Chang

Subjects

Deep neural networks, U-Net, multi-level features, nasopharyngeal carcinoma, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The lesion area of cancer presents complex physiological structures, posing significant challenges for accurate segmentation, which is required in radiotherapy or chemo-radiotherapy. The existing general-purpose segmentation models have made significant progress, but their segmentation performance remains unsatisfactory in specific cancers. To enhance the segmentation performance of nasopharyngeal carcinoma (NPC) MRI images, we develop a segmentation model by incorporating skip connections and receptive blocks within the deep convolutional neural network. We curate a collection of NPC images and evaluate the segmentation performance of the proposed model in comparison with the ground truth segmented images. The similarity between the two types of images is quantified by the Dice Similarity Coefficient (DSC) score, intersection over Union (IoU) score, recall value, and precision value. The mean DSC score was increased to 0.91, and the mean IoU score was improved to 0.84 in the segmentation of our curated NPC images. Our proposed method not only shows excellent performance in segmenting NPC, but also displays its generalization capacity on three public medical image datasets including skin cancer, lung, and chest image databases. The proposed model can leverage multi-layer feature extraction to improve the accuracy of tumor region segmentation. The improved generalization ability suggests that harnessing multi-level features in deep neural networks can improve segmentation performance.

Published

2024

2. CoDock-Ligand: combined template-based docking and CNN-based scoring in ligand binding prediction

Author

Mingwei Pang, Wangqiu He, Xufeng Lu, Yuting She, Liangxu Xie, Ren Kong, and Shan Chang

Subjects

Ligand binding prediction, CASP, CoDock-Ligand, Molecular docking, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract For ligand binding prediction, it is crucial for molecular docking programs to integrate template-based modeling with a precise scoring function. Here, we proposed the CoDock-Ligand docking method that combines template-based modeling and the GNINA scoring function, a Convolutional Neural Network-based scoring function, for the ligand binding prediction in CASP15. Among the 21 targets, we obtained successful predictions in top 5 submissions for 14 targets and partially successful predictions for 4 targets. In particular, for the most complicated target, H1114, which contains 56 metal cofactors and small molecules, our docking method successfully predicted the binding of most ligands. Analysis of the failed systems showed that the predicted receptor protein presented conformational changes in the backbone and side chains of the binding site residues, which may cause large structural deviations in the ligand binding prediction. In summary, our hybrid docking scheme was efficiently adapted to the ligand binding prediction challenges in CASP15.

Published

2023

3. Developing an Improved Cycle Architecture for AI-Based Generation of New Structures Aimed at Drug Discovery

Author

Chun Zhang, Liangxu Xie, Xiaohua Lu, Rongzhi Mao, Lei Xu, and Xiaojun Xu

Subjects

deep learning, molecule generation, bidirectional, CycleGAN, attention, Organic chemistry, QD241-441

Abstract

Drug discovery involves a crucial step of optimizing molecules with the desired structural groups. In the domain of computer-aided drug discovery, deep learning has emerged as a prominent technique in molecular modeling. Deep generative models, based on deep learning, play a crucial role in generating novel molecules when optimizing molecules. However, many existing molecular generative models have limitations as they solely process input information in a forward way. To overcome this limitation, we propose an improved generative model called BD-CycleGAN, which incorporates BiLSTM (bidirectional long short-term memory) and Mol-CycleGAN (molecular cycle generative adversarial network) to preserve the information of molecular input. To evaluate the proposed model, we assess its performance by analyzing the structural distribution and evaluation matrices of generated molecules in the process of structural transformation. The results demonstrate that the BD-CycleGAN model achieves a higher success rate and exhibits increased diversity in molecular generation. Furthermore, we demonstrate its application in molecular docking, where it successfully increases the docking score for the generated molecules. The proposed BD-CycleGAN architecture harnesses the power of deep learning to facilitate the generation of molecules with desired structural features, thus offering promising advancements in the field of drug discovery processes.

Published

2024

4. Application of Machine Learning Methods to Predict the Air Half-Lives of Persistent Organic Pollutants

Author

Ying Zhang, Liangxu Xie, Dawei Zhang, Xiaojun Xu, and Lei Xu

Subjects

persistent organic pollutants, air half-life, quantitative structure–activity relationships, molecular descriptors, machine learning, Organic chemistry, QD241-441

Abstract

Persistent organic pollutants (POPs) are ubiquitous and bioaccumulative, posing potential and long-term threats to human health and the ecological environment. Quantitative structure–activity relationship (QSAR) studies play a guiding role in analyzing the toxicity and environmental fate of different organic pollutants. In the current work, five molecular descriptors are utilized to construct QSAR models for predicting the mean and maximum air half-lives of POPs, including specifically the energy of the highest occupied molecular orbital (HOMO_Energy_DMol3), a component of the dipole moment along the z-axis (Dipole_Z), fragment contribution to SAscore (SAscore_Fragments), subgraph counts (SC_3_P), and structural information content (SIC). The QSAR models were achieved through the application of three machine learning methods: partial least squares (PLS), multiple linear regression (MLR), and genetic function approximation (GFA). The determination coefficients (R2) and relative errors (RE) for the mean air half-life of each model are 0.916 and 3.489% (PLS), 0.939 and 5.048% (MLR), 0.938 and 5.131% (GFA), respectively. Similarly, the determination coefficients (R2) and RE for the maximum air half-life of each model are 0.915 and 5.629% (PLS), 0.940 and 10.090% (MLR), 0.939 and 11.172% (GFA), respectively. Furthermore, the mechanisms that elucidate the significant factors impacting the air half-lives of POPs have been explored. The three regression models show good predictive and extrapolation abilities for POPs within the application domain.

Published

2023

5. A Broad-Spectrum Antiviral Molecule, Protoporphyrin IX, Acts as a Moderator of HIV-1 Capsid Assembly by Targeting the Capsid Hexamer

Author

Da-Wei Zhang, Liangxu Xie, Xiao-Shuang Xu, Yimin Li, and Xiaojun Xu

Subjects

HIV-1 capsid, capsid assembly, hexamer, drug screening, biolayer interferometry, Microbiology, QR1-502

Abstract

ABSTRACT The capsid protein (CA), an essential component of human immunodeficiency virus type 1 (HIV-1), represents an appealing target for antivirals. Small molecules targeting the CAI-binding cavity in the C-terminal domain of HIV-1 CA (CA CTD) confer potent antiviral activities. In this study, we report that a small molecule, protoporphyrin IX (PPIX), targets the HIV-1 CA by binding to this pocket. PPIX was identified via in vitro drug screening, using a homogeneous and time-resolved fluorescence-based assay. CA multimerization and a biolayer interferometry (BLI) assay showed that PPIX promoted CA multimerization and bound directly to CA. The binding model of PPIX to CA CTD revealed that PPIX forms hydrogen bonds with the L211and E212 residues in the CA CTD. Moreover, the BLI assay demonstrated that this compound preferentially binds to the CA hexamer versus the monomer. The superposition of the CAI CTD-PPIX complex and the hexameric CA structure suggests that PPIX binds to the interface formed by the NTD and the CTD between adjacent protomers in the CA hexamer via the T72 and E212 residues, serving as a glue to enhance the multimerization of CA. Taken together, our studies demonstrate that PPIX, a hexamer-targeted CA assembly enhancer, should be a new chemical probe for the discovery of modulators of the HIV-1 capsid assembly. IMPORTANCE CA and its assembled viral core play essential roles in distinct steps during HIV-1 replication, including reverse transcription, integration, nuclear entry, virus assembly, and maturation through CA–CA or CA–host factor interactions. These functions of CA are fundamental for HIV-1 pathogenesis, making it an appealing target for antiviral therapy. In the present study, we identified protoporphyrin IX (PPIX) as a candidate CA modulator that can promote CA assembly and prefers binding the CA hexamer versus the monomer. PPIX, like a glue, bound at the interfaces between CA subunits to accelerate CA multimerization. Therefore, PPIX could be used as a new lead for a CA modulator, and it holds potential research applications.

Published

2023

6. cRNAsp12 Web Server for the Prediction of Circular RNA Secondary Structures and Stabilities

Author

Fengfei Wang, Wei Li, Baiyi Li, Liangxu Xie, Yunguang Tong, and Xiaojun Xu

Subjects

circular RNAs, secondary structure prediction, folding stability, alternative structures, web server, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Circular RNAs (circRNAs) are a novel class of non-coding RNA that, unlike linear RNAs, form a covalently closed loop without the 5′ and 3′ ends. Growing evidence shows that circular RNAs play important roles in life processes and have great potential implications in clinical and research fields. The accurate modeling of circRNAs structure and stability has far-reaching impact on our understanding of their functions and our ability to develop RNA-based therapeutics. The cRNAsp12 server offers a user-friendly web interface to predict circular RNA secondary structures and folding stabilities from the sequence. Through the helix-based landscape partitioning strategy, the server generates distinct ensembles of structures and predicts the minimal free energy structures for each ensemble with the recursive partition function calculation and backtracking algorithms. For structure predictions in the limited structural ensemble, the server also provides users with the option to set the structural constraints of forcing the base pairs and/or forcing the unpaired bases, such that only structures that meet the criteria are enumerated recursively.

Published

2023

7. Deep Convolutional Neural Network for Nasopharyngeal Carcinoma Discrimination on MRI by Comparison of Hierarchical and Simple Layered Convolutional Neural Networks

Author

Li Ji, Rongzhi Mao, Jian Wu, Cheng Ge, Feng Xiao, Xiaojun Xu, Liangxu Xie, and Xiaofeng Gu

Subjects

nasopharyngeal carcinoma, deep learning, image diagnosis, convolutional neural network, artificial intelligence, Medicine (General), R5-920

Abstract

Nasopharyngeal carcinoma (NPC) is one of the most common head and neck cancers. Early diagnosis plays a critical role in the treatment of NPC. To aid diagnosis, deep learning methods can provide interpretable clues for identifying NPC from magnetic resonance images (MRI). To identify the optimal models, we compared the discrimination performance of hierarchical and simple layered convolutional neural networks (CNN). Retrospectively, we collected the MRI images of patients and manually built the tailored NPC image dataset. We examined the performance of the representative CNN models including shallow CNN, ResNet50, ResNet101, and EfficientNet-B7. By fine-tuning, shallow CNN, ResNet50, ResNet101, and EfficientNet-B7 achieved the precision of 72.2%, 94.4%, 92.6%, and 88.4%, displaying the superiority of deep hierarchical neural networks. Among the examined models, ResNet50 with pre-trained weights demonstrated the best classification performance over other types of CNN with accuracy, precision, and an F1-score of 0.93, 0.94, and 0.93, respectively. The fine-tuned ResNet50 achieved the highest prediction performance and can be used as a potential tool for aiding the diagnosis of NPC tumors.

Published

2022

8. Elucidation of Binding Features and Dissociation Pathways of Inhibitors and Modulators in SARS-CoV-2 Main Protease by Multiple Molecular Dynamics Simulations

Author

Lei Xu, Liangxu Xie, Dawei Zhang, and Xiaojun Xu

Subjects

binding features, COVID-19, drug design, Mpro, MCCS, molecular dynamics simulations, Organic chemistry, QD241-441

Abstract

COVID-19 can cause different neurological symptoms in some people, including smell, inability to taste, dizziness, confusion, delirium, seizures, stroke, etc. Owing to the issue of vaccine effectiveness, update and coverage, we still need one or more diversified strategies as the backstop to manage illness. Characterizing the structural basis of ligand recognition in the main protease (Mpro) of SARS-CoV-2 will facilitate its rational design and development of potential drug candidates with high affinity and selectivity against COVID-19. Up to date, covalent-, non-covalent inhibitors and allosteric modulators have been reported to bind to different active sites of Mpro. In the present work, we applied the molecular dynamics (MD) simulations to systematically characterize the potential binding features of catalytic active site and allosteric binding sites in Mpro using a dataset of 163 3D structures of Mpro-inhibitor complexes, in which our results are consistent with the current studies. In addition, umbrella sampling (US) simulations were used to explore the dissociation processes of substrate pathway and allosteric pathway. All the information provided new insights into the protein features of Mpro and will facilitate its rational drug design for COVID-19.

Published

2022

9. Neural networks prediction of the protein-ligand binding affinity with circular fingerprints

Author

Zuode Yin, Wei Song, Baiyi Li, Fengfei Wang, Liangxu Xie, and Xiaojun Xu

Subjects

Biomaterials, Biomedical Engineering, Biophysics, Health Informatics, Bioengineering, Information Systems

Abstract

BACKGROUND: Protein-ligand binding affinity is of significant importance in structure-based drug design. Recently, the development of machine learning techniques has provided an efficient and accurate way to predict binding affinity. However, the prediction performance largely depends on how molecules are represented. OBJECTIVE: Different molecular descriptors are designed to capture different features. The study aims to identify the optimal circular fingerprints for predicting protein-ligand binding affinity with matched neural network architectures. METHODS: Extended-connectivity fingerprints (ECFP) and protein-ligand extended connectivity fingerprints (PLEC) encode circular atomic and bonding connectivity environments with the preference for intra- and inter-molecular features, respectively. Densely-connected neural networks are employed to map the circular fingerprints of protein-ligand complexes to binding affinities RESULTS: The performance of neural networks is sensitive to the parameters used for ECFP and PLEC fingerprints. The R2_score of the evaluated ECFP and PLEC fingerprints reaches 0.52 and 0.49, higher than that of the improperly set ECFP and PLEC fingerprints with R2_score of 0.45 and 0.38, respectively. Additionally, compared to the predictions from the standalone fingerprints, the ECFP+PLEC conjoint ones slightly improve the prediction accuracy with R2_score of approximately 0.55. CONCLUSION: Both intra- and inter-molecular structural features encoded in the circular fingerprints contribute to the protein-ligand binding affinity. Optimizing the parameters of ECFP and PLEC can enhance performance. The conjoint fingerprint scheme can be generally extended to other molecular descriptors for enhanced feature engineering and improved predictive performance.

Published

2023

10. Computational prediction of Lee retention indices of polycyclic aromatic hydrocarbons by using machine learning

Author

Linkang Sun, Min Zhang, Liangxu Xie, Xiaojun Xu, Peng Xu, and Lei Xu

Subjects

Pharmacology, Drug Discovery, Organic Chemistry, Molecular Medicine, Biochemistry

Abstract

Given the difficult of experimental determination, quantitative structure-property relationship (QSPR) and deep learning (DL) provide an important tool to predict physicochemical property of chemical compounds. In this paper, partial least squares (PLS), genetic function approximation (GFA), and deep neural network (DNN) were used to predict the Lee retention index (Lee-RI) of PAHs in SE-52 and DB-5 stationary phases. Four molecular descriptors, molecular weight (MW), quantitative estimate of drug-likeness (QED), atomic charge weighted negative surface area (Jurs_PNSA_3), and relative negative charge (Jurs_RNCG) were selected to construct regression models based on genetic algorithm. For SE-52, PLS model showed best prediction power, followed by DNN and GFA. The relative error (RE), root mean square error (RMSE), and regression coefficient (R

Published

2022

11. Counterion distribution around a polyelectrolyte confined in a metal–organic framework

Author

Liangxu Xie, Kwong-Yu Chan, and Vanessa Chi-Ying Li

Subjects

General Chemical Engineering, Modeling and Simulation, General Materials Science, General Chemistry, Condensed Matter Physics, Information Systems

Published

2022

12. COVID-19 Imaging-based AI Research - A Literature Review

Author

Liangxu Xie, Ren Kong, Hong Zhang, Shan Chang, Lili Zhang, and Cheng Ge

Subjects

Diagnostic Imaging, SARS-CoV-2, Process (engineering), business.industry, Computer science, Supervised learning, COVID-19, Machine learning, computer.software_genre, Identification (information), COVID-19 Testing, Artificial Intelligence, Medical imaging, Humans, Unsupervised learning, Radiology, Nuclear Medicine and imaging, Segmentation, Artificial intelligence, Medical diagnosis, business, Transfer of learning, computer

Abstract

Background: The new coronavirus disease 2019 (COVID-19) is spreading rapidly around the world. Artificial Intelligence (AI) assisted identification and detection of diseases is an effective method of medical diagnosis. Objectives: To present recent advances in AI-assisted diagnosis of COVID-19, we introduce major aspects of AI in the process of diagnosing COVID-19. Methods: In this paper, we firstly cover the latest collection and processing methods of datasets of COVID-19. The processing methods mainly include building public datasets, transfer learning, unsupervised learning and weakly supervised learning, semi-supervised learning methods and so on. Secondly, we introduce the algorithm application and evaluation metrics of AI in medical imaging segmentation and automatic screening. Then, we introduce the quantification and severity assessment of infection in COVID-19 patients based on image segmentation and automatic screening. Finally, we analyze and point out the current AI-assisted diagnosis of COVID-19 problems, which may provide useful clues for future work. Conclusion: AI is critical for COVID-19 diagnosis. Combining chest imaging with AI can not only save time and effort, but also provide more accurate and efficient medical diagnosis results.

Published

2022

13. A Broad-Spectrum Antiviral Molecule, Protoporphyrin IX, Acts as a Moderator of HIV-1 Capsid Assembly by Targeting the Capsid Hexamer

Author

Da-Wei Zhang, Liangxu Xie, Xiao-Shuang Xu, Yimin Li, and Xiaojun Xu

Subjects

Microbiology (medical), Infectious Diseases, General Immunology and Microbiology, Ecology, Physiology, Genetics, Cell Biology

Abstract

The capsid protein (CA), an essential component of human immunodeficiency virus type 1 (HIV-1), represents an appealing target for antivirals. Small molecules targeting the CAI-binding cavity in the C-terminal domain of HIV-1 CA (CA CTD) confer potent antiviral activities. In this study, we report that a small molecule, protoporphyrin IX (PPIX), targets the HIV-1 CA by binding to this pocket. PPIX was identified via

Published

2022

14. In silico prediction of boiling point, octanol-water partition coefficient, and retention time index of polycyclic aromatic hydrocarbons through machine learning

Author

Linkang Sun, Min Zhang, Liangxu Xie, Qian Gao, Xiaojun Xu, and Lei Xu

Subjects

Pharmacology, Machine Learning, Octanols, Drug Discovery, Organic Chemistry, Molecular Medicine, Water, Quantitative Structure-Activity Relationship, Transition Temperature, Polycyclic Aromatic Hydrocarbons, Biochemistry

Abstract

Polycyclic aromatic hydrocarbons (PAHs), a special class of persistent organic pollutants (POPs) with two or more aromatic rings, have received extensive attention owing to their carcinogenic, mutagenic, and teratogenic effects. Quantitative structure-property relationship (QSPR) is powerful chemometric method to correlate structural descriptors of PAHs with their physicochemical properties. In this manuscript, a QSPR study of PAHs was performed to predict their boiling point (bp), octanol-water partition coefficient (LogK

Published

2022

15. Landscape Zooming toward the Prediction of RNA Cotranscriptional Folding

Author

Xiaojun Xu, Lei Jin, Liangxu Xie, and Shi-Jie Chen

Subjects

Kinetics, RNA Folding, Transcription, Genetic, Escherichia coli, Nucleic Acid Conformation, RNA, Thermodynamics, Physical and Theoretical Chemistry, Article, Computer Science Applications

Abstract

RNA molecules fold as they are transcribed. Cotranscriptional folding of RNA plays a critical role in RNA functions in vivo. Present computational strategies focus on simulations where large structural changes may not be completely sampled. Here we describe an alternative approach to predicting cotranscriptional RNA folding by zooming in and out of the RNA folding energy landscape. By classifying the RNA structural ensemble into “partitions” based on long, stable helices, we zoom out of the landscape and predict the overall slow folding kinetics from the inter-partition kinetic network, and for each inter-partition transition, we zoom in on the landscape to simulate the kinetics. Applications of the model to the 117-nucleotide E. coli SRP RNA and the 59-nucleotide HIV-1 TAR RNA show agreements with the experimental data and new structural and kinetic insights into biologically significant conformational switches and pathways for these important systems. This approach, by zooming in/out of RNA folding landscape at different resolutions, might allow us to treat large RNAs in vivo with transcriptional pause, transcription speed, and other in vivo effects.

Published

2022

16. Deep Learning Assisted Diagnosis of Nasopharyngeal Carcinoma: A Comparison of Hierarchical And Shallow Convolutional Neural Networks

Author

Li Ji, Rongzhi Mao, Xiaofeng Gu, Cheng Ge, Feng Xiao, Jian Wu, Xiaojun Xu, and Liangxu Xie

Published

2022

17. Molecular dynamics simulation of hydration and free energy of ions in nanochannels of polyelectrolyte threaded metal organic framework and the impacts on selective ion transport

Author

Liangxu Xie, Kwong-Yu Chan, and Vanessa Chi-Ying Li

Subjects

Materials Chemistry, Physical and Theoretical Chemistry, Condensed Matter Physics, Spectroscopy, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials

Published

2022

18. A promoted copper-catalysed Azide-alkyne cycloaddition (CuAAC) for broad spectrum peptide-engineered implants

Author

Guansong Hu, Kunzhong Guo, Lin Wang, Zhou Fang, Yingjun Wang, Yan Fan, Liangxu Xie, Junjian Chen, and Haiyan Zhou

Subjects

Sodium ascorbate, chemistry.chemical_classification, Chemistry, General Chemical Engineering, Biomaterial, Alkyne, Peptide, General Chemistry, Combinatorial chemistry, Industrial and Manufacturing Engineering, Cycloaddition, chemistry.chemical_compound, Sodium borohydride, In vivo, Environmental Chemistry, Azide

Abstract

As an effective strategy to develop novel implants with a biomolecule, the efficiency of a copper-catalysed azide-alkyne cycloaddition (CuAAC) urgently requires improvement. Herein, we constructed a facile CuAAC system with catalytic CuSO4/sodium borohydride (CuAAC-Bor). As Cu nanoclusters (CuNCs) formed in situ, they showed stronger efficiency in immobilizing 41 types of peptides on Ti implants than traditional CuAAC with CuSO4/sodium ascorbate. Then, we mechanically revealed the significance of peptide size on CuAAC efficiency by all-atom molecular dynamics simulation and machine learning, and found that larger peptides preferred to adhere to Ti and CuNCs to increase their reaction opportunity. With CuAAC-Bor, HHC36-engineered implants strongly inhibited 5 types of clinical bacteria in vitro and prevented infection in vivo, and RGD-, DGEA-, QK- or YGFGG-engineered implants had high biocompatibilities with HUVECs/hBMSCs in vitro. Moreover, we demonstrated that QK-engineered implants prepared with CuAAC-Bor promoted the osteogenic differentiation of hBMSCs via the PI3K/Akt signalling pathway and triggered angiogenesis and osteogenesis in vivo. Our study shows that this facile and highly efficient CuAAC-Bor system holds high promise for the preparation of novel biomaterial surfaces.

Published

2022