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<p>PREFACE ix</p> <p>CONTRIBUTORS xiii</p> <p><b>PART I</b></p> <p>1 X-Ray Crystallography of Biological Macromolecules: Fundamentals and Applications 3<br /> <i>Antonio L. Llamas-Saiz and Mark J. van Raaij</i></p> <p>2 Nuclear Magnetic Resonance Methods for Studying Soluble, Fibrous, and Membrane-Embedded Proteins 23<br /> <i>Victoria A. Higman</i></p> <p>3 Small-Angle X-Ray Scattering Applied to Proteins in Solution 49<br /> <i>Leandro Ramos Souza Barbosa, Francesco Spinozzi, Paolo Mariani, and Rosangela Itri</i></p> <p>4 Analyzing the Solution State of Protein Structure, Interactions, and Ligands by Spectroscopic Methods 73<br /> <i>Veronica I. Dodero and Paula V. Messina</i></p> <p>5 Resolving Membrane-Bound Protein Orientation and Conformation by Neutron Reflectivity 99<br /> <i>Hirsh Nanda</i></p> <p>6 Investigating Protein Interactions at Solid Surfaces—In Situ, Nonlabeling Techniques 113<br /> <i>Olof Svensson, Javier Sotres, and Alejandro Barrantes</i></p> <p>7 Calorimetric Methods to Characterize the Forces Driving Macromolecular Association and Folding Processes 139<br /> <i>Conceic¸ ˜ao A.S.A. Minetti, Peter L. Privalov, and David P. Remeta</i></p> <p>8 Virtual Ligand Screening Against Comparative Models of Proteins 179<br /> <i>Hao Fan</i></p> <p>9 Atomistic and Coarse-Grained Molecular Dynamics Simulations of Membrane Proteins 193<br /> <i>Thomas J. Piggot, Peter J. Bond, and Syma Khalid</i></p> <p><b>PART II</b></p> <p>10 Preparation of Nanomaterials Based on Peptides and Proteins 209<br /> <i>Yujing Sun and Zhuang Li</i></p> <p>11 Natural Fibrous Proteins: Structural Analysis, Assembly, and Applications 219<br /> <i>Mark J. van Raaij and Anna Mitraki</i></p> <p>12 Amyloid-Like Fibrils: Origin, Structure, Properties, and Potential Technological Applications 233<br /> <i>Pablo Taboada, Silvia Barbosa, Josue Juarez, Manuel-Alatorre Meda, and Výctor Mosquera</i></p> <p>13 Proteins and Peptides in Biomimetic Polymeric Membranes 283<br /> <i>Alfredo Gonzalez-Perez</i></p> <p>14 Study of Proteins and Peptides at Interfaces By Molecular Dynamics Simulation Techniques 291<br /> <i>David Poger and Alan E. Mark</i></p> <p>15 A Single-Molecule Approach to Explore the Role of the Solvent Environment in Protein Folding 315<br /> <i>Katarzyna Tych and Lorna Dougan</i></p> <p>16 Enhanced Functionality of Peroxidases By Its Immobilization at The Solid–Liquid Interface of Mesoporous Materials and Nanoparticles 335<br /> <i>Jose Campos-Teran, Iker Inarritu, Jorge Aburto, and Eduardo Torres</i></p> <p>17 Superactivity of Enzymes in Supramolecular Hydrogels 353<br /> <i>Ye Zhang and Bing Xu</i></p> <p>18 Surfactant Proteins and Natural Biofoams 365<br /> <i>Malcolm W. Kennedy and Alan Cooper</i></p> <p>19 Promiscuous Enzymes 379<br /> <i>Luis F. Olguin</i></p> <p>20 Thermodynamics and Kinetics of Mixed Protein/Surfactant Adsorption Layers at Liquid Interfaces 389<br /> <i>Reinhard Miller, E.V. Aksenenko, V.S. Alahverdjieva, V.B. Fainerman, C.S. Kotsmar, J. Kragel, M.E. Leser, J. Maldonado-Valderrama, V. Pradines, C. Stefaniu, A. Stocco, and R. Wustneck</i></p> <p>21 Application of Force Spectroscopy Methods to the Study of Biomaterials 429<br /> <i>Chuan Xu and Erika F. Merschrod S.</i></p> <p>22 Protein Gel Rheology 437<br /> <i>Katie Weigandt and Danilo Pozzo</i></p> <p>23 Exploring Biomolecular Thermodynamics in Aqueous and Nonaqueous Environments using Time-Resolved Photothermal Methods 449<br /> <i>Randy W. Larsen, Carissa M. Vetromile, William A. Maza, Khoa Pham, Jaroslava Miksovska</i></p> <p>INDEX 473</p>

<p><b>JUAN M. RUSO</b> is currently Associate Professor in the Department of Applied Physics at the University of Santiago de Compostela, Spain. He has contributed to more than 100 publications on a broad range of physical, chemical, and biophysics studies. His research interests include protein ligand interactions, thermal stabilization of protein, Phase behavior, and self-assembly processes in soft matter systems, biocompatible materials design, and nanocarrier design for targeted drug delivery.</p> <p><b>ÁNGEL PIÑEIRO</b> is an IPP Research Fellow at the Department of Applied Physics of the University of Santiago de Compostela, Spain. His current research interests include the design and characterization of self-assembled systems as well as the study of macromolecules in solution, embedded in membranes or at interfaces. His work is mainly based on computational methods including multiscale molecular dynamics simulations and the development of software for the analysis of different experimental properties.</p>

<p><b>Explores new applications emerging from our latest understanding of proteins in solution and at interfaces</b></p> <p>Proteins in solution and at interfaces increasingly serve as the starting point for exciting new applications, from biomimetic materials to nanoparticle patterning. This book surveys the state of the science in the field, offering investigators a current understanding of the characteristics of proteins in solution and at interfaces as well as the techniques used to study these characteristics. Moreover, the authors explore many of the new and emerging applications that have resulted from the most recent studies. Topics include protein and protein aggregate structure; computational and experimental techniques to study protein structure, aggregation, and adsorption; proteins in non-standard conditions; and applications in biotechnology.</p> <p><i>Proteins in Solution and at Interfaces</i> is divided into two parts:</p> <ul> <li><b>Part One</b> introduces concepts as well as theoretical and experimental techniques that are used to study protein systems, including X-ray crystallography, nuclear magnetic resonance, small angle scattering, and spectroscopic methods</li> <li><b>Part Two</b> examines current and emerging applications, including nanomaterials, natural fibrous proteins, and biomolecular thermodynamics</li> </ul> <p>The book's twenty-three chapters have been contributed by leading experts in the field. These contributions are based on a thorough review of the latest peer-reviewed findings as well as the authors' own research experience. Chapters begin with a discussion of core concepts and then gradually build in complexity, concluding with a forecast of future developments.</p> <p>Readers will not only gain a current understanding of proteins in solution and at interfaces, but also will discover how theoretical and technical developments in the field can be translated into new applications in material design, genetic engineering, personalized medicine, drug delivery, biosensors, and biotechnology.</p>

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