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The genetic, molecular, and cellular mechanisms of neural development are essential for understanding evolution and disorders of neural systems. Recent advances in genetic, molecular, and cell biological methods have generated a massive increase in new information, but there is a paucity of comprehensive and up-to-date syntheses, references, and historical perspectives on this important subject. The Comprehensive Developmental Neuroscience series is designed to fill this gap, offering the most thorough coverage of this field on the market today and addressing all aspects of how the nervous system and its components develop. Particular attention is paid to the effects of abnormal development and on new psychiatric/neurological treatments being developed based on our increased understanding of developmental mechanisms. Each volume in the series consists of review style articles that average 15-20pp and feature numerous illustrations and full references. Volume 1 offers 48 high level articles devoted mainly to patterning and cell type specification in the developing central and peripheral nervous systems. - Series offers 144 articles for 2904 full color pages addressing ways in which the nervous system and its components develop - Features leading experts in various subfields as Section Editors and article Authors - All articles peer reviewed by Section Editors to ensure accuracy, thoroughness, and scholarship - Volume 1 sections include coverage of mechanisms which: control regional specification, regulate proliferation of neuronal progenitors and control differentiation and survival of specific neuronal subtypes, and controlling development of non-neural cells
The Novartis Foundation Series is a popular collection of the proceedings from Novartis Foundation Symposia, in which groups of leading scientists from a range of topics across biology, chemistry and medicine assembled to present papers and discuss results. The Novartis Foundation, originally known as the Ciba Foundation, is well known to scientists and clinicians around the world.
This text explores the use of cellular automata in modeling pattern formation in biological systems. It describes several mathematical modeling approaches utilizing cellular automata that can be used to study the dynamics of interacting cell systems both in simulation and in practice. New in this edition are chapters covering cell migration, tissue development, and cancer dynamics, as well as updated references and new research topic suggestions that reflect the rapid development of the field. The book begins with an introduction to pattern-forming principles in biology and the various mathematical modeling techniques that can be used to analyze them. Cellular automaton models are then discussed in detail for different types of cellular processes and interactions, including random movement, cell migration, adhesive cell interaction, alignment and cellular swarming, growth processes, pigment cell pattern formation, tissue development, tumor growth and invasion, and Turing-type patterns and excitable media. In the final chapter, the authors critically discuss possibilities and limitations of the cellular automaton approach in modeling various biological applications, along with future research directions. Suggestions for research projects are provided throughout the book to encourage additional engagement with the material, and an accompanying simulator is available for readers to perform their own simulations on several of the models covered in the text. QR codes are included within the text for easy access to the simulator. With its accessible presentation and interdisciplinary approach, Cellular Automaton Modeling of Biological Pattern Formation is suitable for graduate and advanced undergraduate students in mathematical biology, biological modeling, and biological computing. It will also be a valuable resource for researchers and practitioners in applied mathematics, mathematical biology, computational physics, bioengineering, and computer science. PRAISE FOR THE FIRST EDITION “An ideal guide for someone with a mathematical or physical background to start exploring biological modelling. Importantly, it will also serve as an excellent guide for experienced modellers to innovate and improve their methodologies for analysing simulation results.” —Mathematical Reviews
This new volume of Methods in Cell Biology looks at micropatterning in cell biology and includes chapters on protein photo-patterning on PEG with benzophenone, laser-directed cell printing and dip pen nanolithography. The cutting-edge material in this comprehensive collection is intended to guide researchers for years to come. - Includes sections on micropatterning in 2D with photomask, maskless micropatterning and 2D nanopatterning - Chapters are written by experts in the field - Cutting-edge material
The mechanics underlying the form and structure of biological tissues is being increasingly investigated and appreciated, with new results appearing at a fast pace. Cellular Patterns covers the salient elements of this thriving field of research in a textbook style, including both historic landmark results and recent achievements. By building on concepts such as packing, confinement, surface tension, and elastic instabilities, the book explains the structure and the shape of sheet-like and bulk tissues by adapting the mechanics of continuous media to living matter. It reviews experimental results and empirical laws, and wherever possible, it discusses more than a single theoretical interpretation of a given phenomenon. The in-depth treatment of technical details, the many boxes summarizing essential physical and biological ideas, and an extensive set of problems make this book suitable as a complementary textbook for a graduate course in biophysics and as a standalone reference for students and researchers in biophysics, bioengineering, and mathematical biology interested in the mechanics of tissue. Features: Provides an overview of patterns and shapes seen in animal tissues in addition to an interpretation of these structures in terms of physical forces and processes Contains detailed analysis and a critical comparison of mechanical models of cells, tissues, and morphogenetic movements Presents a visually rich style which is accessible to physicists and biologists alike
This book vividly describes how complex and integrated movements can arise from the properties and behaviors of biological molecules. It provides a uniquely integrated account in which the latest findings from biophysics and molecular biology are put into the context of living cells. This second edition is updated throughout with recent advances in the field and has a completely revised and redrawn art program. The text is suitable for advanced undergraduates, graduate students, and for professionals wishing for an overview of this field.
Fast-moving and ever-changing, stem cell science and research presents ongoing ethical and legal challenges in many countries. Each development and innovation throws up new challenges. This is the case even where new developments initially seem to solve old dilemmas. Sometimes it becomes evident that new science does not in fact solve old problems and, for that reason, the ethical issues remain. In recognition of this, this book presents innovative and creative analyses of a range of ethical and legal challenges raised by stem cell research and its potential and actual application. The editors.
Known as the bible of biomedical engineering, The Biomedical Engineering Handbook, Fourth Edition, sets the standard against which all other references of this nature are measured. As such, it has served as a major resource for both skilled professionals and novices to biomedical engineering. Molecular, Cellular, and Tissue Engineering, the fourth volume of the handbook, presents material from respected scientists with diverse backgrounds in molecular biology, transport phenomena, physiological modeling, tissue engineering, stem cells, drug delivery systems, artificial organs, and personalized medicine. More than three dozen specific topics are examined, including DNA vaccines, biomimetic systems, cardiovascular dynamics, biomaterial scaffolds, cell mechanobiology, synthetic biomaterials, pluripotent stem cells, hematopoietic stem cells, mesenchymal stem cells, nanobiomaterials for tissue engineering, biomedical imaging of engineered tissues, gene therapy, noninvasive targeted protein and peptide drug delivery, cardiac valve prostheses, blood substitutes, artificial skin, molecular diagnostics in personalized medicine, and bioethics.
Table of Contents Reporter cells: - Yeast Based Sensors by Mifumi Shimomura-Shimizu and Isao Karube - Mammalian Cell-Based Sensor Systems by Pratik Banerjee, Briana Franz, and Arun K. Bhunia - Fluorescent and Bioluminescent Cell-Based Sensors: Strategies for Their Preservation by Amol Date, Patrizia Pasini, and Sylvia Daunert - Electrochemical Cell-Based Sensors by Eliora Z. Ron and Judith Rishpon - Microbial Cell Arrays by Tal Elad, Jin Hyung Lee, Man Bock Gu, and Shimshon Belkin Devices: - Surface Functionalization for Protein and Cell Patterning by Pascal Colpo , Ana Ruiz , Laura Ceriotti , and François Rossi - Fiber-Optic Based Cell Sensors by Evgeni Eltzov and Robert S. Marks - Electronic Interfacing with Living Cells by James T. Fleming - On-Chip Detection of Cellular Activity by R. Almog , R. Daniel , S. Vernick , A. Ron , H. Ben-Yoav, and Y. Shacham-Diamand