As the mysteries stored in our DNA have been more completely revealed, scientists have begun to face the extraordinary challenge of unraveling the int- cate network of protein-protein interactions established by that DNA fra- work. It is increasingly clear that proteins continuously interact with one another in a highly regulated fashion to determine cell fate, such as proliferation, diff- entiation, or death. These protein-protein interactions enable and exert str- gent control over DNA replication, RNA transcription, protein translation, macromolecular assembly and degradation, and signal transduction; essentially all cellular functions involve protein-protein interactions. Thus, protein-p- tein interactions are fundamental for normal physiology in all organisms. Alt- ation of critical protein-protein interactions is thought to be involved in the development of many diseases, such as neurodegenerative disorders, cancers, and infectious diseases. Therefore, examination of when and how protein-p- tein interactions occur and how they are controlled is essential for understa- ing diverse biological processes as well as for elucidating the molecular basis of diseases and identifying potential targets for therapeutic interventions. Over the years, many innovative biochemical, biophysical, genetic, and computational approaches have been developed to detect and analyze p- tein-protein interactions. This multitude of techniques is mandated by the diversity of physical and chemical properties of proteins and the sensitivity of protein-protein interactions to cellular conditions.

The chemokines family of small proteins are involved in numerous b- logical processes ranging from hematopoiesis, angiogenesis, and basal l- kocyte trafficking to the extravasation and tissue infiltration of leukocytes in response to inflammatory agents, tissue damage, and bacterial or viral infection. Chemokines exert their effects through a family of seven G-protein coupled transmembrane receptors. Worldwide interest in the chemokine field surged dramatically early in 1996, with the finding that certain chemokine receptors were the elusive coreceptors, required along with CD4, for HIV infection. Today, though over 40 human chemokines have been described, the n- ber of chemokine receptors lags behind-only 17 human chemokine receptors have been identified so far. What has emerged over the years is that most chemokine receptors bind several distinct ligands, and indeed the majority of chemokines are able to bind to multiple chemokine receptors, explaining to some extent the apparent disparity in the numbers of chemokines and rec- tors. Yet in spite of the apparent redundancy in chemokine/chemokine rec- tor interactions, it is clear that in vivo, spatial, temporal, and indeed cell- and tissue-specific expression of both chemokines and their receptors are imp- tant factors in determining the precise nature of cellular infiltrates in phy- ological and pathological processes.

The first book to chronicle how innovation in laboratory designs for botanical research energized the emergence of physiological plant ecology as a vibrant subdiscipline   Laboratory innovation since the mid-twentieth century has powered advances in the study of plant adaptation, evolution, and ecosystem function. The phytotron, an integrated complex of controlled-environment greenhouse and laboratory spaces, invented by Frits W. Went in the 1950s, set off a worldwide laboratory movement and transformed the plant sciences. Sharon Kingsland explores this revolution through a comparative study of work in the United States, France, Australia, Israel, the USSR, and Hungary.   These advances in botanical research energized physiological plant ecology. Case studies explore the development of phytotron spinoffs such as mobile laboratories, rhizotrons, and ecotrons. Scientific problems include the significance of plant emissions of volatile organic compounds, symbiosis between plants and soil fungi, and the discovery of new pathways for photosynthesis as an adaptation to hot, dry climates. The advancement of knowledge through synthesis is a running theme: linking disciplines, combining laboratory and field research, and moving across ecological scales from leaf to ecosystem. The book also charts the history of modern scientific responses to the emerging crisis of food insecurity in the era of global warming.

This book explicates the optical controls of antiferromagnetic spins by intense terahertz (THz) electromagnetic waves. The book comprises two key components: (1) the experimental demonstration of the enhancement of a THz magnetic field using a split-ring resonator (SRR) and (2) the control of the direction of magnetization by using the enhanced THz magnetic field to break the symmetry of optically-induced phase transition. These make up the first step leading to future spintronics devices. In the beginning of the book, the author reviews the basics of the ultrafast laser and nonlinear optical techniques as well as the previously achieved experiments to control spin dynamics by THz magnetic fields. In this context, a new experimental protocol is described, in which electron spins in a ferromagnetic material are redirected at the unprecedented level in cooperation with the enhanced THz magnetic field. Subsequently, the author demonstrates that the THz magnetic field is significantly amplified as a nearfield around the SRR structured metamaterial, which is implemented by measuring spin precession in a solid. At the end, the author presents the key experiment in which the amplified THz magnetic nearfield is applied to the weak ferromagnet ErFeO3 along with the femtosecond near-infrared pulse, demonstrating the successful control of symmetry breaking of the spin system due to coherent control of the optically-induced spin reorientation phase transition pathways. The comprehensive introductory review in this book allows readers to overview state-of-the-art terahertz spectroscopic techniques. In addition, the skillful description of the experiments is highly informative for readers in ultrafast magnonics, ultrafast optics, terahertz technology and plasmonic science.

Since the advent of hybridoma technology more than two decades ago, numerous antibodies have entered the clinical setting as potent therapeutic agents. Their repeated application in humans, however, is limited by the development of human antimouse antibodies (HAMA) in the recipient, leading to allergic re- tions against the foreign murine protein and rapid neutralization. To circumvent these limitations many new antibodies have recently been tailored through recombinant antibody technology. The initial clinical data show encouraging results, thus demonstrating the potential of these new therapeutic agents. The purpose of Recombinant Antibodies for Cancer Therapy is to present a collection of detailed protocols in recombinant antibody technology. It is pri- rily addressed to scientists working on recombinant antibodies as well as cli- cians involved with antibody-based therapies. As with other volumes of this series, we placed the main focus on providing detailed protocols describing procedures step-by-step. Moreover, each protocol supplies a troubleshooting guide containing detailed information on possible problems and hints for pot- tial solutions. Antibody technology is a subject of constant and rapid change. This volume, therefore, does not attempt to cover all possible current experimental approaches in the field. Rather, we present carefully selected protocols, written by competent authors who have successfully verified the particular method described. Given our own professional backgrounds and interest in oncology, we chose to conc- trate chiefly on therapeutic agents for cancer patients.

Purification of Laboratory Chemicals: Part One, Physical Techniques, Chemical Techniques, Organic Chemicals, Ninth Edition describes contemporary methods for the purification of chemical compounds. The work includes tabulated methods taken from literature for purifying thousands of individual commercially available chemical substances. To help in applying this information, the more common processes currently used for purification in chemical laboratories and new methods are discussed. For dealing with substances not separately listed, another chapter is included, setting out the usual methods for purifying specific classes of compounds. Laboratory workers, whether carrying out research or routine work, will invariably need to consult this book. Apart from the procedures described, the large amount of physical data about listed chemicals is essential. This fully updated, revised and expanded new edition includes the purification of many new substances that have been available commercially since 2017, along with previously available substances which have found new applications.

The rapid progress on somatic embryogenesis and its prospects for potential application to improving woody plants prompted us to edit this book initially in three volumes, and now an additional three more volumes. We were all convinced that such a treatise was needed and would be extremely useful to researchers and students. This volume 6 is dedicated to Prof. Harry Waris, Helsinki, Finland, who did pioneer work on somatic embryogenesis during the time when Prof. Steward and others were actively engaged in this area. His former student Prof. Liisa Simols, University of Helsinki, Finland, has written a dedication Harry Waris, a pioneer in somatic embryogenesis' to her teacher Prof. Waris. This volume is divided into three sections and contains a total of 26 chapters. Section A comprises seven chapters covering topics such as: Historical insights into some contemporary problems in somatic embryogenesis (SE); Thin cell layer for somatic embryogenesis induction in woody trees; SE in tropical fruit and forest trees; SE in fruit and forest arid trees; Status of SE in Indian forest trees; SE research in fruit trees in India; Applications of SE for the improvement of tropical fruit trees. Section B comprises 15 chapters, dealing with: SE in oil palm, hazelnut (Corylus avellana L.), pistachio (Pistacia vera L.), Araucaria angustifolia, Quercus suber, Aspidosperma polyneuron, Acacia senegal, Simmondsia chiensis, Cupressus sempervirens, pecan (Carya illinoinensis), rattan (Calamus spp.), tamarillo (Cyphomandra betacea, longan (Dimocarpus longan Lor.), Aegle marmelos, and Euonymus europaeus. Section C comprises three chapters related to cryo-storage of citrus, conifers and rubber. All the chaptershave been peer-reviewed and revised accordingly to improve the quality of the chapters. We are thankful to all: (a) contributory authors for their co-operation in submitting manuscripts in time, and (b) reviewers for spending their valuable time in reviewing the manuscripts.

The development of new methodologies has played a key role in the advancement of all areas of research. Specifically, the initial advances in our understanding of lipoprotein structure and metabolism were made possible by the development of ultracentrifugation and electrophoretic techniques. More recently, the advent of molecular biological techniques opened possibilities that were unthinkable just a few decades ago. The use of the analytical ult- centrifuge to study plasma lipoproteins began in the 1940s with the work of Mutzenbecher, McFarlene, Pedersen, Gofman, Lindgren, and Elliot. Another crucial step, during the 1950s, was the development of this tool as a prepa- tive technique by Havel, Eder, and Bragdon, among others. This technolo- cal progress allowed investigators to "dig" deeper into the structure of these complex macromolecules made of lipids and proteins, and permitted inves- gators to continue unraveling the physical and chemical characteristics of the proteins associated with lipoprotein particles (apolipoproteins) and the enzymes involved in their processing. This information led to both a better understanding of the biological functions of the lipoprotein fractions and their constituents, and creation of a more comprehensive overall scheme for plasma lipoprotein metabolism. Several gaps in this puzzle were filled through the work of Goldstein and Brown, who elucidated the structure and role of the low-density lipoprotein - ceptor. This was the first identified among a profusion of receptors that are key for the cellular catabolism of these particles.

Spark scientific curiosity from a young age with this six-level course through an enquiry-based approach and active learning. Collins International Primary Science fully meets the requirements of the Cambridge Primary Science Curriculum Framework from 2020 and has been carefully developed for a range of international contexts. The course is organised into four main strands: Biology, Chemistry, Physics and Earth and Space and the skills detailed under the 'Thinking and Working Scientifically' strand are introduced and taught in the context of those areas. For each Student's Book at Stages 1 to 6, we offer: A full colour and highly illustrated Student's Book Photo-rich spreads show that science is 'real' and puts it into context Earth and Space content covers the new curriculum framework Thinking and Working Scientifically deepens and enhances the delivery of Science skills Actively learn through practical activities that don't require specialist equipment or labs Scaffolding allows students of varying abilities to work with common content and meet learning objectives Supports Cambridge Global Perspectives (TM) with activities that develop and practise key skills Provides learner support as part of a set of resources for the Cambridge Primary Science curriculum framework (0097) from 2020 This series is endorsed by Cambridge Assessment International Education to support the new curriculum framework 0097 from 2020.

This completely revised edition explores novel discoveries in bacterial genomic research, with a focus on technical and computational improvements as well as methods used for bacterial pangenome analysis, which relies on microbiome studies and metagenomic data. Beginning with up-to-date sequencing methods, the book continues with sections covering methods for deep phylogenetic analysis, the role of metagenomic data in understanding the genomics of the many yet uncultured bacteria, progress in genome-to-phenome inference, as well as computational genomic tools. Written for the highly successful Methods in Molecular Biology series, chapters include the type of practical detail necessary for reproducible results in the lab. Authoritative and up-to-date, Bacterial Pangenomics: Methods and Protocols, Second Edition serves as an ideal guide for both highly qualified investigators in bacterial genomics and for less experienced researchers, including students and teachers, who could use a reference for approaching genomic analysis and genome data.

Bored of the same old dinner-party chitchat? Spice up your soirees, impress your guests and show up your brother-in-law with these hilarious, and sometimes dangerous, after-dinner tricks and challenges. Twenty-one daredevil tricks are illustrated along with step-by-step instructions and explanations of the science behind them. From sabering a bottle of champagne to hammering a needle through a coin, each of these feats is guaranteed to wow your guests.

Spark scientific curiosity from a young age with this six-level course through an enquiry-based approach and active learning. Collins International Primary Science fully meets the requirements of the Cambridge Primary Science Curriculum Framework from 2020 and has been carefully developed for a range of international contexts. The course is organised into four main strands: Biology, Chemistry, Physics and Earth and Space and the skills detailed under the 'Thinking and Working Scientifically' strand are introduced and taught in the context of those areas. For each Student's Book at Stages 1 to 6, we offer: A full colour and highly illustrated Student's Book Photo-rich spreads show that science is 'real' and puts it into context Earth and Space content covers the new curriculum framework Thinking and Working Scientifically deepens and enhances the delivery of Science skills Actively learn through practical activities that don't require specialist equipment or labs Scaffolding allows students of varying abilities to work with common content and meet learning objectives Supports Cambridge Global Perspectives (TM) with activities that develop and practise key skills Provides learner support as part of a set of resources for the Cambridge Primary Science curriculum framework (0097) from 2020 This series is endorsed by Cambridge Assessment International Education to support the new curriculum framework 0097 from 2020.

Spark scientific curiosity from a young age with this six-level course through an enquiry-based approach and active learning. Collins International Primary Science fully meets the requirements of the Cambridge Primary Science Curriculum Framework from 2020 and has been carefully developed for a range of international contexts. The course is organised into four main strands: Biology, Chemistry, Physics and Earth and Space and the skills detailed under the ‘Thinking and Working Scientifically’ strand are introduced and taught in the context of those areas. For each Workbook at Stages 1 to 6, we offer: A write-in Workbook linked to the Student’s Book New language development activities help build science vocabulary Earth and Space content covers the new curriculum framework Thinking and Working Scientifically deepens and enhances the delivery of Science skills Actively learn through practical activities that don’t require specialist equipment or labs Scaffolding allows students of varying abilities to work with common content and meet learning objectives Supports Cambridge Global Perspectives™ with activities that develop and practise key skills Provides learner support as part of a set of resources for the Cambridge Primary Science curriculum framework (0097) from 2020 This series is endorsed by Cambridge Assessment International Education to support the new curriculum framework 0097 from 2020.

This detailed book compiles a series of laboratory protocols covering the most important aspects of R-loop biology. Beginning with a range of methods allowing for the detection of DNA-RNA hybrids, as well as their purification and visualization by electron microscopy, the volume continues with methods based on the use of RNase H-derived tools to detect DNA-RNA hybrids in vitro and in vivo. Several protocols permit studying non-canonical RNA nucleotides in the R-loop context, as well as a number of specific protocols devoted to the investigation of R-loop topology and their functional roles in the biology of mitochondria and telomeres. Finally, a large block of chapters is dedicated to different methods allowing genome-wide mapping of DNA-RNA hybrids in various organisms. Written for the highly successful Methods in Molecular Biology series, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Authoritative and practical, R-Loops: Methods and Protocols serves as an ideal resource for those working on R-loop homeostasis but also to scientists studying such areas of molecular and cell biology as genome integrity, DNA replication and repair, chromatin remodeling, transcription, RNA processing, modification and export, as well as for researchers elucidating the molecular mechanisms of cancer and genetic diseases.

Spark scientific curiosity from a young age with this six-level course through an enquiry-based approach and active learning. Collins International Primary Science fully meets the requirements of the Cambridge Primary Science Curriculum Framework from 2020 and has been carefully developed for a range of international contexts. The course is organised into four main strands: Biology, Chemistry, Physics and Earth and Space and the skills detailed under the ‘Thinking and Working Scientifically’ strand are introduced and taught in the context of those areas. For each Workbook at Stages 1 to 6, we offer: A write-in Workbook linked to the Student’s Book New language development activities help build science vocabulary Earth and Space content covers the new curriculum framework Thinking and Working Scientifically deepens and enhances the delivery of Science skills Actively learn through practical activities that don’t require specialist equipment or labs Scaffolding allows students of varying abilities to work with common content and meet learning objectives Supports Cambridge Global Perspectives™ with activities that develop and practise key skills Provides learner support as part of a set of resources for the Cambridge Primary Science curriculum framework (0097) from 2020 This series is endorsed by Cambridge Assessment International Education to support the new curriculum framework 0097 from 2020.

This volume provides a comprehensive reference for researchers aiming to bring new techniques and approaches to their scientific research using urodeles. Chapters are authored by leaders in the field and meant to guide readers through laboratory colony husbandry, traditional molecular techniques, experimental manipulation and surgeries, bioinformatics and genomics, transgenics and lineage-tracing, and physiological and organismal techniques. In addition to laboratory methods, this volume highlights techniques developed for field studies and work with wild-caught animals. Written in the successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible protocols, and notes on troubleshooting and avoiding known pitfalls. Authoritative and state-of-the-art, Methods in Salamander Research aims to be a practical guide for researchers interested in deploying new methodologies in their lab or in the field.

Developing microscale chemistry experiments, using small quantities of chemicals and simple equipment, has been a recent initiative in the UK. Microscale chemistry experiments have several advantages over conventional experiments: They use small quantities of chemicals and simple equipment which reduces costs; The disposal of chemicals is easier due to the small quantities; Safety hazards are often reduced and many experiments can be done quickly; Using plastic apparatus means glassware breakages are minimised; Practical work is possible outside a laboratory. Microscale Chemistry is a book of such experiments designed for use in schools and colleges, and the ideas behind the experiments in it come from many sources, including chemistry teachers from all around the world. Current trends indicate that with the likelihood of further environmental legislation, the need for microscale chemistry teaching techniques and experiments is likely to grow. This book should serve as a guide in this process.

VOLUME 25

Reviews in Computational Chemistry

Kenny B. Lipkowitz and Thomas R. Cundari

This Volume, Like Those Prior To It, Features Pedagogically Driven Reviews By Experts In Various Fields Of Computational Chemistry. Volume 25 Contains: Eight Chapters Covering The Glass Transition In Polymer Melts, Atomistic Modeling Of Friction, The Computation Of Free Volume, Structural Order And Entropy Of Liquids And Glasses, The Reactivity Of Materials At Extreme Conditions, Magnetic Properties Of Transition Metal Clusters, Multiconfigurational Quantum Methods For The Treatment Of Heavy Metals, Recursive Solutions To Large Eigenvalue Problems, And The Development And Uses Of Artificial Intelligence In Chemistry.

From Reviews of the Series

"Reviews in Computational Chemistry remains the most valuable reference to methods and techniques in computational chemistry."
--JOURNAL OF MOLECULAR GRAPHICS AND MODELLING

"One cannot generally do better than to try to find an appropriate article in the highly successful Reviews in Computational Chemistry. The basic philosophy of the editors seems to be to help the authors produce chapters that are complete, accurate, clear, and accessible to experimentalists (in particular) and other nonspecialists (in general)."
--JOURNAL OF THE AMERICAN CHEMICAL SOCIETY

This first edited Volume on IgY-Technology, addresses the historical and dynamic development of IgY-applications. The authors cover the biological basis and theoretical context, methodological guidance, and applications of IgY-Technology. A focus is laid on the use of IgY-antibodies for prophylactic/therapeutic purposes in human and veterinary medicine. Aside from applications, the chapters also offer an evolutionary understanding of the IgY molecule, IgY receptors and practical prerequisites to produce IgY-antibodies. Guidance is given for every step of the process. Starting with an introduction to hens as a model species and including hen husbandry, hen egg-laying capacity and total IgY outcomes. Readers will also learn about immunization techniques, the advantages and limitations of different IgY extraction methods, as well as storage stability of the final product. The last part of the volume highlights hands-on aspects of applications, such as IgY delivery strategies, new methods to produce monoclonal IgY-antibodies or production of functional IgY fragments by phage-display as well as commercial exploitation of the technology. Thus, this book is a valuable resource and guide for Scientists, Clinicians and Health Product Developers in both human and veterinary medicine.

This book presents a detailed look at experimental and computational techniques for accurate structure determination of free molecules. The most fundamental property of a molecule is its structure - it is a prerequisite for determining and understanding most other important properties of molecules. The determination of accurate structures is hampered by a myriad of factors, subjecting the collected data to non-negligible systematic errors. This book explains the origin of these errors and how to mitigate and even avoid them altogether. It features a detailed comparison of the different experimental and computation methods, explaining their interplay and the advantages of their combined use. Armed with this information, the reader will be able to choose the appropriate methods to determine - to a great degree of accuracy - the relevant molecular structure.

Analytical techniques are powerful tools in a chemist's armoury. Spectroscopic data and chemical information are used routinely in laboratories to follow a chemical reaction or elucidate a chemical structure. However, the sophistication of the analytical techniques used changes rapidly, hence the routinely used method of today can all too readily be superseded by the new technology of tomorrow. More Modern Chemical Techniques identifies some applications of the important chemical techniques in use today that are less well known in schools and colleges and which illustrate how chemistry is using state-of-the-art technology to push back the frontiers of the subject. Examples include: elemental analysis such as atomic absorption spectrometry and inductively coupled plasma techniques; separations including electrophoresis, structure determination (eg x-ray diffraction and optical microscopy); and sampling and sample preparation.

Introduction to Statistical Analysis of Laboratory Data presents a detailed discussion of important statistical concepts and methods of data presentation and analysis * Provides detailed discussions on statistical applications including a comprehensive package of statistical tools that are specific to the laboratory experiment process * Introduces terminology used in many applications such as the interpretation of assay design and validation as well as fit for purpose procedures including real world examples * Includes a rigorous review of statistical quality control procedures in laboratory methodologies and influences on capabilities * Presents methodologies used in the areas such as method comparison procedures, limit and bias detection, outlier analysis and detecting sources of variation * Analysis of robustness and ruggedness including multivariate influences on response are introduced to account for controllable/uncontrollable laboratory conditions

This is the first book written on using Blender (an open-source visualization suite widely used in the entertainment and gaming industries) for scientific visualization. It is a practical and interesting introduction to Blender for understanding key parts.

Emily Calandrelli, MIT engineer and scientist, shares exhilarating experiments for junior scientists and their lab assistants, ranging from homemade ice cream to disappearing ink. The book features 50 experiments using easy-to-find grocery store items. Each experiment includes a scientific explanation, a Hypothesize section to record the scientist's assumptions, science vocabulary that applies STEM research to real life (did you know that ketchup is a non-Newtonian fluid?), and Try This! prompts with even more ways to experiment with your experiment. Let the science spark curiosity and critical thinking; grab your goggles and your trusted assistant and get started!