05530nam 22007091 450 991013903910332120200520144314.03-527-66516-13-527-66514-53-527-66517-X(CKB)2550000001157308(EBL)1524298(OCoLC)862371218(SSID)ssj0001163812(PQKBManifestationID)11743493(PQKBTitleCode)TC0001163812(PQKBWorkID)11164433(PQKB)10707958(OCoLC)868979349(MiAaPQ)EBC1524298(MiAaPQ)EBC4044464(Au-PeEL)EBL1524298(CaPaEBR)ebr10799628(CaONFJC)MIL540351(PPN)178872997(EXLCZ)99255000000115730820131107h20142014 uy 0engur|n|---|||||txtccrScaffold hopping in medicinal chemistry /edited by Nathan BrownWeinheim, Germany :Wiley-VCH,[2014]©20141 online resource (326 p.)Methods and principles in medicinal chemistry ;volume 58Description based upon print version of record.3-527-33364-9 1-306-09100-4 Includes bibliographical references and index.Scaffold Hopping in Medicinal Chemistry; Contents; List of Contributors; Preface; A Personal Foreword; Part One: Scaffolds: Identification, Representation Diversity, and Navigation; 1 Identifying and Representing Scaffolds; 1.1 Introduction; 1.2 History of Scaffold Representations; 1.3 Functional versus Structural Molecular Scaffolds; 1.4 Objective and Invariant Scaffold Representations; 1.4.1 Molecular Frameworks; 1.4.2 Scaffold Tree; 1.5 Maximum Common Substructures; 1.6 Privileged Scaffolds; 1.7 Conclusions; References; 2 Markush Structures and Chemical Patents; 2.1 Introduction2.2 Encoding Markush Structures2.2.1 The r_group Record; 2.2.1.1 Exact R Groups; 2.2.1.2 Inexact R Groups; 2.2.1.3 Fused R Groups; 2.2.2 The Menguin Program; 2.2.3 Correspondence between the MIL File and the Markush Structure; 2.3 The Search Algorithm; 2.3.1 Matching R Groups; 2.3.1.1 Exact R Groups; 2.3.1.2 Inexact R Groups; 2.3.1.3 Fused R Groups; 2.3.1.4 Hydrogen Atoms; 2.3.1.5 Managing Multiple Fragment/R Group Matches; 2.4 Using Periscope for Scaffold Hopping; 2.4.1 Substructure Searching; 2.4.2 Free-Wilson Analysis; 2.4.3 Fast Followers; 2.5 Conclusions; References3 Scaffold Diversity in Medicinal Chemistry Space3.1 Introduction; 3.1.1 Scaffold Representation; 3.1.2 What Do We Mean by Scaffold Diversity?; 3.2 Scaffold Composition of Medicinal Chemistry Space; 3.2.1 Natural Products as a Source of Novel Medicinal Chemistry Scaffolds; 3.2.2 Enumerating Potential Medicinal Chemistry Scaffolds; 3.2.3 Using Scaffold Composition to Interpret Bioactivity Data; 3.3 Metrics for Quantifying the Scaffold Diversity of Medicinal Chemistry Space; 3.4 Visualizing the Scaffold Diversity of Medicinal Chemistry Space; 3.5 Conclusions; References4 Scaffold Mining of Publicly Available Compound Data4.1 Introduction; 4.2 Scaffold Definition; 4.3 Selectivity of Scaffolds; 4.3.1 Privileged Substructures; 4.3.2 Target Community-Selective Scaffolds; 4.3.3 Target-Selective Scaffolds; 4.4 Target Promiscuity of Scaffolds; 4.4.1 Promiscuous BM Scaffolds and CSKs; 4.4.2 Scaffold-Target Family Profiles; 4.4.3 Promiscuous Scaffolds in Drugs; 4.5 Activity Cliff-Forming Scaffolds; 4.5.1 Activity Cliff Concept; 4.5.2 Multitarget Cliff-Forming Scaffolds; 4.6 Scaffolds with Defined Activity Progression; 4.6.1 Activity Profile Sequences4.6.2 Conserved Scaffolds4.7 Scaffold Diversity of Pharmaceutical Targets; 4.7.1 Scaffold Hopping Potential; 4.7.2 Structural Relationships between Scaffolds; 4.7.3 Scaffold Hopping in Virtual Screening; 4.8 Conclusions; References; 5 Exploring Virtual Scaffold Spaces; 5.1 Introduction; 5.1.1 Virtual Chemistry; 5.1.2 Chemical Space; 5.1.3 Scaffold Definition; 5.2 The Comprehensive Enumeration of Parts of Chemical Space; 5.2.1 Fragments; 5.2.2 Ring Systems; 5.2.3 Reagents; 5.3 The Iterative Generation of Virtual Compounds; 5.3.1 Transformations; 5.3.2 Manual Selection of Chemical Modifications5.3.3 Analog GeneratorsThis first systematic treatment of the concept and practice of scaffold hopping shows the tricks of the trade and provides invaluable guidance for the reader's own projects.The first section serves as an introduction to the topic by describing the concept of scaffolds, their discovery, diversity and representation, and their importance for finding new chemical entities. The following part describes the most common tools and methods for scaffold hopping, whether topological, shape-based or structure-based. Methods such as CATS, Feature Trees, Feature Point Pharmacophores (FEPOPS), and SMethods and principles in medicinal chemistry ;v. 58.Pharmaceutical chemistryDrug interactionsPharmaceutical chemistry.Drug interactions.615.19Brown Nathan828243MiAaPQMiAaPQMiAaPQBOOK9910139039103321Scaffold hopping in medicinal chemistry1918966UNINA