Data mining in drug discovery

Written for drug developers rather than computer scientists, this monograph adopts a systematic approach to mining scientifi c data sources, covering all key steps in rational drug discovery, from compound screening to lead compound selection and personalized medicine. Clearly divided into four sections, the first part discusses the different data sources available, both commercial and non-commercial, while the next section looks at the role and value of data mining in drug discovery. The third part compares the most common applications and strategies for polypharmacology, where data mining can substantially enhance the research effort. The final section of the book is devoted to systems biology approaches for compound testing. Throughout the book, industrial and academic drug discovery strategies are addressed, with contributors coming from both areas, enabling an informed decision on when and which data mining tools to use for one's own drug discovery project.

Preface A Personal Foreword PART ONE: Data Sources PROTEIN STRUCTURAL DATABASES IN DRUG DISCOVERY The Protein Data Bank: The Unique Public Archive of Protein Structures PDB-Related Databases for Exploring Ligand-Protein Recognition The sc-PDB, A Collection of Pharmacologically Relevant Protein-Ligand Complexes Conclusions PUBLIC DOMAIN DATABASES FOR MEDICINAL CHEMISTRY Introduction Databases of Small Molecule Binding and Bioactivity Trends in Medicinal Chemistry Data Directions Summary CHEMICAL ONTOLOGIES FOR STANDARDIZATION, KNOWLEDGE DISCOVERY, AND DATA MINING Introduction Background Chemical Ontologies Standardization Knowledge Discovery Data Mining Conclusions BUILDING A CORPORATE CHEMICAL DATABASE TOWARD SYSTEMS BIOLOGY Introduction Setting the Scene Dealing with Chemical Structures Increased Accuracy of the Registration of Data Implementation of the Platform Linking Chemical Information to Analytical Data Linking Chemicals to Bioactivity Data Conclusions PART TWO: Analysis and Enrichment DATA MINING OF PLANT METABOLIC PATHWAYS Introduction Pathway Representation Pathway Management Platforms Obtaining Pathway Information Constructing Organism-Specific Pathway Databases Conclusions THE ROLE OF DATA MINING IN THE IDENTIFICATION OF BIOACTIVE COMPOUNDS VIA HIGH-THROUGHPUT SCREENING Introduction to the HTS Process: The Role of Data Mining Relevant Data Architectures for the Analysis of HTS Data Analysis of HTS Data Identification of New Compounds via Compound Set Enrichment and Docking Conclusions THE VALUE OF INTERACTIVE VISUAL ANALYTICS IN DRUG DISCOVERY: AN OVERVIEW Creating Informative Visualizations Lead Discovery and Optimization Genomics USING CHEMOINFORMATICS TOOLS FROM R Introduction System Call Shared Library Call Wrapping Java Archives Conclusions PART THREE: Applications to Polypharmacology CONTENT DEVELOPMENT STRATEGIES FOR THE SUCCESSFUL IMPLEMENTATION OF DATA MINING TECHNOLOGIES Introduction Knowledge Challenges in Drug Discovery Case Studies Knowledge-Based Data Mining Technologies Future Trends and Outlook APPLICATIONS OF RULE-BASED METHODS TO DATA MINING OF POLYPHARMACOLOGY DATA SETS Introduction Materials and Methods Results Discussion Conclusion DATA MINING USING LIGAND PROFILING AND TARGET FISHING Introduction In Silico Ligand Profiling Methods Summary and Conclusions PART FOUR: System Biology Approaches DATA MINING OF LARGE-SCALE MOLECULAR AND ORGANISMAL TRAITS USING AN INTEGRATIVE AND MODULAR ANALYSIS APPROACH Rapid Technological Advances Revolutionize Quantitative Measurements in Biology and Medicine Genome-Wide Association Studies Reveal Quantitative Trait Loci Integration of Molecular and Organismal Phenotypes Is Required for Understanding Causative Links Reduction of Complexity of High-Dimensional Phenotypes in Terms of Modules Biclustering Algorithms Ping-Pong Algorithm Module Commonalities Provide Functional Insights Module Visualization Application of Modular Analysis Tools for Data Mining of Mammalian Data Sets Outlook SYSTEMS BIOLOGY APPROACHES FOR COMPOUND TESTING Introduction Step 1: Design Experiment for Data Production Step 2: Compute Systems Response Profiles Step 3: Identify Perturbed Biological Networks Step 4: Compute Network Perturbation Amplitudes Step 5: Compute the Biological Impact Factor Conclusions