Computation in bioinformatics : multidisciplinary applications

Computation in bioinformatics multidisciplinary applications

COMPUTATION IN BIOINFORMATICS Bioinformatics is a platform between the biology and information technology and this book provides readers with an understanding of the use of bioinformatics tools in new drug design. The discovery of new solutions to pandemics is facilitated through the use of promisin...

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Detalles Bibliográficos
Otros Autores: Balamurugan, S., Prof. editor (editor)
Formato: Libro electrónico
Idioma:Inglés
Publicado: Hoboken, NJ : John Wiley & Sons, Inc 2021.
Colección:Artificial intelligence and soft computing for industrial transformation.
Materias:
Bioinformatics.
Ver en Biblioteca Universitat Ramon Llull:https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009645676706719
Tabla de Contenidos:
  • Cover
  • Half-Title Page
  • Series Page
  • Title Page
  • Copyright Page
  • Contents
  • Preface
  • 1 Bioinfomatics as a Tool in Drug Designing
  • 1.1 Introduction
  • 1.2 Steps Involved in Drug Designing
  • 1.2.1 Identification of the Target Protein/Enzyme
  • 1.2.2 Detection of Molecular Site (Active Site) in the Target Protein
  • 1.2.3 Molecular Modeling
  • 1.2.4 Virtual Screening
  • 1.2.5 Molecular Docking
  • 1.2.6 QSAR (Quantitative Structure-Activity Relationship)
  • 1.2.7 Pharmacophore Modeling
  • 1.2.8 Solubility of Molecule
  • 1.2.9 Molecular Dynamic Simulation
  • 1.2.10 ADME Prediction
  • 1.3 Various Softwares Used in the Steps of Drug Designing
  • 1.4 Applications
  • 1.5 Conclusion
  • References
  • 2 New Strategies in Drug Discovery
  • 2.1 Introduction
  • 2.2 Road Toward Advancement
  • 2.3 Methodology
  • 2.3.1 Target Identification
  • 2.3.2 Docking-Based Virtual Screening
  • 2.3.3 Conformation Sampling
  • 2.3.4 Scoring Function
  • 2.3.5 Molecular Similarity Methods
  • 2.3.6 Virtual Library Construction
  • 2.3.7 Sequence-Based Drug Design
  • 2.4 Role of OMICS Technology
  • 2.5 High-Throughput Screening and Its Tools
  • 2.6 Chemoinformatic
  • 2.6.1 Exploratory Data Analysis
  • 2.6.2 Example Discovery
  • 2.6.3 Pattern Explanation
  • 2.6.4 New Technologies
  • 2.7 Concluding Remarks and Future Prospects
  • References
  • 3 Role of Bioinformatics in Early Drug Discovery: An Overview and Perspective
  • 3.1 Introduction
  • 3.2 Bioinformatics and Drug Discovery
  • 3.2.1 Structure-Based Drug Design (SBDD)
  • 3.2.2 Ligand-Based Drug Design (LBDD)
  • 3.3 Bioinformatics Tools in Early Drug Discovery
  • 3.3.1 Possible Biological Activity Prediction Tools
  • 3.3.2 Possible Physicochemical and Drug-Likeness Properties Verification Tools
  • 3.3.3 Possible Toxicity and ADME/T Profile Prediction Tools
  • 3.4 Future Directions With Bioinformatics Tool.
  • 3.5 Conclusion
  • Acknowledgements
  • References
  • 4 Role of Data Mining in Bioinformatics
  • 4.1 Introduction
  • 4.2 Data Mining Methods/Techniques
  • 4.2.1 Classification
  • 4.2.1.1 Statistical Techniques
  • 4.2.1.2 Clustering Technique
  • 4.2.1.3 Visualization
  • 4.2.1.4 Induction Decision Tree Technique
  • 4.2.1.5 Neural Network
  • 4.2.1.6 Association Rule Technique
  • 4.2.1.7 Classification
  • 4.3 DNA Data Analysis
  • 4.4 RNA Data Analysis
  • 4.5 Protein Data Analysis
  • 4.6 Biomedical Data Analysis
  • 4.7 Conclusion and Future Prospects
  • References
  • 5 In Silico Protein Design and Virtual Screening
  • 5.1 Introduction
  • 5.2 Virtual Screening Process
  • 5.2.1 Before Virtual Screening
  • 5.2.2 General Process of Virtual Screening
  • 5.2.2.1 Step 1 (The Establishment of the Receptor Model)
  • 5.2.2.2 Step 2 (The Generation of Small-Molecule Libraries)
  • 5.2.2.3 Step 3 (Molecular Docking)
  • 5.2.2.4 Step 4 (Selection of Lead Protein Compounds)
  • 5.3 Machine Learning and Scoring Functions
  • 5.4 Conclusion and Future Prospects
  • References
  • 6 New Bioinformatics Platform-Based Approach for Drug Design
  • 6.1 Introduction
  • 6.2 Platform-Based Approach and Regulatory Perspective
  • 6.3 Bioinformatics Tools and Computer-Aided Drug Design
  • 6.4 Target Identification
  • 6.5 Target Validation
  • 6.6 Lead Identification and Optimization
  • 6.7 High-Throughput Methods (HTM)
  • 6.8 Conclusion and Future Prospects
  • References
  • 7 Bioinformatics and Its Application Areas
  • 7.1 Introduction
  • 7.2 Review of Bioinformatics
  • 7.3 Bioinformatics Applications in Different Areas
  • 7.3.1 Microbial Genome Application
  • 7.3.2 Molecular Medicine
  • 7.3.3 Agriculture
  • 7.4 Conclusion
  • References
  • 8 DNA Microarray Analysis: From Affymetrix CEL Files to Comparative Gene Expression
  • 8.1 Introduction
  • 8.2 Data Processing.
  • 8.2.1 Installation of Workflow
  • 8.2.2 Importing the Raw Data for Processing
  • 8.2.3 Retrieving Sample Annotation of the Data
  • 8.2.4 Quality Control
  • 8.3 Normalization of Microarray Data Using the RMA Method
  • 8.3.1 Background Correction
  • 8.3.2 Normalization
  • 8.3.3 Summarization
  • 8.4 Statistical Analysis for Differential Gene Expression
  • 8.5 Conclusion
  • References
  • 9 Machine Learning in Bioinformatics
  • 9.1 Introduction and Background
  • 9.1.1 Bioinformatics
  • 9.1.2 Text Mining
  • 9.1.3 IoT Devices
  • 9.2 Machine Learning Applications in Bioinformatics
  • 9.3 Machine Learning Approaches
  • 9.4 Conclusion and Closing Remarks
  • References
  • 10 DNA-RNA Barcoding and Gene Sequencing
  • 10.1 Introduction
  • 10.2 RNA
  • 10.3 DNA Barcoding
  • 10.3.1 Introduction
  • 10.3.2 DNA Barcoding and Molecular Phylogeny
  • 10.3.3 Ribosomal DNA (rDNA) of the Nuclear Genome (nuDNA)-ITS
  • 10.3.4 Chloroplast DNA
  • 10.3.5 Mitochondrial DNA
  • 10.3.6 Molecular Phylogenetic Analysis
  • 10.3.7 Metabarcoding
  • 10.3.8 Materials for DNA Barcoding
  • 10.4 Main Reasons of DNA Barcoding
  • 10.5 Limitations/Restrictions of DNA Barcoding
  • 10.6 RNA Barcoding
  • 10.6.1 Overview of the Method
  • 10.7 Methodology
  • 10.7.1 Materials Required
  • 10.7.2 Barcoded RNA Sequencing High-Level Mapping of Single-Neuron Projections
  • 10.7.3 Using RNA to Trace Neurons
  • 10.7.4 A Life Conservation Barcoder
  • 10.7.5 Gene Sequencing
  • 10.7.5.1 DNA Sequencing Methods
  • 10.7.5.2 First-Generation Sequencing Techniques
  • 10.7.5.3 Maxam's and Gilbert's Chemical Method
  • 10.7.5.4 Sanger Sequencing
  • 10.7.5.5 Automation in DNA Sequencing
  • 10.7.5.6 Use of Fluorescent-Marked Primers and ddNTPs
  • 10.7.5.7 Dye Terminator Sequencing
  • 10.7.5.8 Using Capillary Electrophoresis
  • 10.7.6 Developments and High-Throughput Methods in DNA Sequencing
  • 10.7.7 Pyrosequencing Method.
  • 10.7.8 The Genome Sequencer 454 FLX System
  • 10.7.9 Illumina/Solexa Genome Analyzer
  • 10.7.10 Transition Sequencing Techniques
  • 10.7.11 Ion-Torrent's Semiconductor Sequencing
  • 10.7.12 Helico's Genetic Analysis Platform
  • 10.7.13 Third-Generation Sequencing Techniques
  • 10.8 Conclusion
  • Abbreviations
  • Acknowledgement
  • References
  • 11 Bioinformatics in Cancer Detection
  • 11.1 Introduction
  • 11.2 The Era of Bioinformatics in Cancer
  • 11.3 Aid in Cancer Research via NCI
  • 11.4 Application of Big Data in Developing Precision Medicine
  • 11.5 Historical Perspective and Development
  • 11.6 Bioinformatics-Based Approaches in the Study of Cancer
  • 11.6.1 SLAMS
  • 11.6.2 Module Maps
  • 11.6.3 COPA
  • 11.7 Conclusion and Future Challenges
  • References
  • 12 Genomic Association of Polycystic Ovarian Syndrome: Single-Nucleotide Polymorphisms and Their Role in Disease Progression
  • 12.1 Introduction
  • 12.2 FSHR Gene
  • 12.3 IL-10 Gene
  • 12.4 IRS-1 Gene
  • 12.5 PCR Primers Used
  • 12.6 Statistical Analysis
  • 12.7 Conclusion
  • References
  • 13 An Insight of Protein Structure Predictions Using Homology Modeling
  • 13.1 Introduction
  • 13.2 Homology Modeling Approach
  • 13.2.1 Strategies for Homology Modeling
  • 13.2.2 Procedure
  • 13.3 Steps Involved in Homology Modeling
  • 13.3.1 Template Identification
  • 13.3.2 Sequence Alignment
  • 13.3.3 Backbone Generation
  • 13.3.4 Loop Modeling
  • 13.3.5 Side Chain Modeling
  • 13.3.6 Model Optimization
  • 13.3.6.1 Model Validation
  • 13.4 Tools Used for Homology Modeling
  • 13.4.1 Robetta
  • 13.4.2 M4T (Multiple Templates)
  • 13.4.3 I-Tasser (Iterative Implementation of the Threading Assembly Refinement)
  • 13.4.4 ModBase
  • 13.4.5 Swiss Model
  • 13.4.6 PHYRE2 (Protein Homology/Analogy Recognition Engine 2)
  • 13.4.7 Modeller
  • 13.4.8 Conclusion
  • Acknowledgement
  • References.
  • 14 Basic Concepts in Proteomics and Applications
  • 14.1 Introduction
  • 14.2 Challenges on Proteomics
  • 14.3 Proteomics Based on Gel
  • 14.4 Non-Gel-Based Electrophoresis Method
  • 14.5 Chromatography
  • 14.6 Proteomics Based on Peptides
  • 14.7 Stable Isotopic Labeling
  • 14.8 Data Mining and Informatics
  • 14.9 Applications of Proteomics
  • 14.10 Future Scope
  • 14.11 Conclusion
  • References
  • 15 Prospects of Covalent Approaches in Drug Discovery: An Overview
  • 15.1 Introduction
  • 15.2 Covalent Inhibitors Against the Biological Target
  • 15.3 Application of Physical Chemistry Concepts in Drug Designing
  • 15.4 Docking Methodologies-An Overview
  • 15.5 Importance of Covalent Targets
  • 15.6 Recent Framework on the Existing Docking Protocols
  • 15.7 SN2 Reactions in the Computational Approaches
  • 15.8 Other Crucial Factors to Consider in the Covalent Docking
  • 15.8.1 Role of Ionizable Residues
  • 15.8.2 Charge Regulation
  • 15.8.3 Charge-Charge Interactions
  • 15.9 QM/MM Approaches
  • 15.10 Conclusion and Remarks
  • Acknowledgements
  • References
  • Index
  • Also of Interest
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  • EULA.

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