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Developmental biology is one of the most exciting and fast-growing fields - day. In part, this is so because the subject matter deals with the innately fascinating biological events?changes in form, structure, and function of the organism. The other reason for much of the excitement in developmental biology is that the field has truly become the unifying melting pot of biology, and provides a framework that integrates anatomy, physiology, genetics, biochemistry, and cellular and molecular biology, as well as evolutionary biology. No longer is the study of embryonic development merely "embryology." In fact, development biology has produced important paradigms for both basic and clinical biomedical sciences alike. Though modern developmental biology has its roots in "experimental embry- ogy" and the even more classical "chemical embryology," the recent explosive and remarkable advances in developmental biology are critically linked to the advent of the "cellular and molecular biology revolution." The impressive arsenal of expe- mental and analytical tools derived from cell and molecular biology, which promise to continue to expand, together with the exponentially developing sophistication in fu- tional imaging and information technologies, guarantee that the study of the devel- ing embryo will contribute one of the most captivating areas of biological research in the next millennium.

Developmental biology is one of the most exciting and fast-growing fields - day. In part, this is so because the subject matter deals with the innately fascinating biological events?changes in form, structure, and function of the organism. The other reason for much of the excitement in developmental biology is that the field has truly become the unifying melting pot of biology, and provides a framework that integrates anatomy, physiology, genetics, biochemistry, and cellular and molecular biology, as well as evolutionary biology. No longer is the study of embryonic development merely "embryology." In fact, development biology has produced important paradigms for both basic and clinical biomedical sciences alike. Though modern developmental biology has its roots in "experimental embry- ogy" and the even more classical "chemical embryology," the recent explosive and remarkable advances in developmental biology are critically linked to the advent of the "cellular and molecular biology revolution." The impressive arsenal of expe- mental and analytical tools derived from cell and molecular biology, which promise to continue to expand, together with the exponentially developing sophistication in fu- tional imaging and information technologies, guarantee that the study of the devel- ing embryo will contribute one of the most captivating areas of biological research in the next millennium.

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The molecular biology revolution has transformed developmental biology into one of the most exciting and fruitful fields in experimental biomedical research today. In Developmental Biology Protocols, established leaders in this field demonstrate this achievement with a comprehensive collection of cutting-edge protocols for studying and analyzing the events of embryonic development. Drawing on state-of-the-art cellular and molecular techniques, as well as new and sophisticated imaging and information technologies, this first volume of three presents readily reproducible methods for establishing and characterizing several widely used experimental model systems, for both the study of developmental patterns and morphogenesis, and the examination of embryo structure and function. In addition, there are step-by-step methods for the analysis of cell lineage, the production and use of chimeras, and the experimental molecular manipulation of embryos, including the application of viral vectors.
The second and third volumes in this seminal set complete today's widest-ranging collection of techniques designed to decipher the exact cellular, molecular, and genetic mechanisms that control the form, structure, and function of the developing embryo. Volume 2 describes state-of-the-art methods for the study of organogenesis, the analysis of abnormal development and teratology, the screening and mapping of novel genes and mutations, and the application of transgenesis, including the production of transgenic animals and gene knockouts. No less innovative, Volume 3 introduces powerful techniques for the manipulation of developmental gene expression and function, the analysis of gene expression, the characterization of tissue morphogenesis and development, the in vitro study of differentiation and development, and the genetic analysis of developmental models of diseases. Highly practical and richly annotated, the three volumes of Developmental Biology Protocols describe multiple experimental systems and details techniques adopted from the broadest array of biomedical disciplines. Every researcher will not only better understand the principles, background, and rationale for how form and function are elaborated in an organism, but also gain full practical access to today's best methods for its analysis.

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Part I. Introduction. Developmental Biology Protocols: Overview I, Rocky S. Tuan and Cecilia W. Lo. Part II. Systems: Production, Culture, and Storage. Rearing Larvae of Sea Urchins and Sea Stars for Developmental Studies, Christopher J. Lowe and Gregory A. Wray. Large-Scale Culture and Preparation of Sea Urchin Embryos for Isolation of Transcriptional Regulatory Proteins, James A. Coffman and Patrick S. Leahy. The Chick Embryo as a Model System for Analyzing Mechanisms of Development, Diana K. Darnell and Gary C. Schoenwolf. Culture of Avian Embryos, Diana K. Darnell and Gary C. Schoenwolf. Ex Ovo Culture of Avian Embryos, Tamao Ono. Culture of Preimplantation Mouse Embryos, Adam S. Doherty and Richard M. Schultz. In Vitro Culture of Rodent Embryos During Early Postimplantation Period, Masahiko Fujinaga. Cryopreservation of Mouse Embryos, Jean Richa. Part III. Developmental Pattern and Morphogenesis. Studying Head and Brain Development in Drosophila, Robert Finkelstein. Bioassays of Inductive Interactions in Amphibian Development, Takashi Ariizumi, Kazuhiro Takano, Makoto Asashima, and George M. Malacinski. Gastrulation and Early Mesodermal Patterning in Vertebrates, Gary C. Schoenwolf and Jodi L. Smith. Craniofacial Development of Avian and Rodent Embryos, Brian K. Hall and Tom Miyake. Examination of the Axial Skeleton of Fetal Rodents, Michael G. Narotsky and John M. Rogers. Cardiac Morphogenesis and Dysmorphogenesis: An Immunohistochemical Approach, B. Rush Waller III and Andy Wessels. Part IV. Embryo Structure and Function. Application of Plastic Embedding for Sectioning Whole-Mount Immunostained Early Vertebrate Embryos, Kersti K. Linask and Takeshi Tsuda. Confocal Microscopy of Live Xenopus Oocytes, Eggs, and Embryos, Carolyn A. Larabell. Whole-Mount Immunolabeling of Embryos by Microinjection: Increased Detection Levels of Extracellular and Cell Surface Epitopes, Charles D. Little and Christopher J. Drake. Confocal Laser Scanning Microscopy of Morphology and Apoptosis in Organogenesis-Stage Mouse Embryos, Robert M. Zucker, E. Sidney Hunter III, and John M. Rogers. Embryo/Fetal Topographical Analysis by Fluorescence Microscopy and Confocal Laser Scanning Microscopy, Robert M. Zucker and John M. Rogers. Magnetic Resonance Imaging Analysis of Embryos, Bradley R. Smith. Optical Coherence Tomography Imaging in Developmental Biology, Stephen A. Boppart, Mark E. Brezinski, and James G. Fujimoto. Ultrasound Backscatter Microscopy of Mouse Embryos, Daniel H. Turnbull. Use of Doppler Echocardiography to Monitor Embryonic Mouse Heart Function, Kersti K. Linask and James C. Huhta. Calcium Imaging and Cell-Cell Signaling, Diane C. Slusarski and Victor G. Corces. Acquisition, Display, and Analysis of Digital Three-Dimensional and Time-Lapse (Four-Dimensional) Data Sets Using Free Software Applications, Charles F. Thomas and John G. White. Part V. Cell Lineage Analysis. Cell Lineage Analysis: Applications of Green Fluorescent Protein, Magdalena Zernicka-Goetz and Jonathon Pines. Cell Lineage Analysis: X-Inactivation Mosaics, Seong-SengTan, Leanne Godinho, and Patrick P. L. Tam. Retroviral Cell Lineage Analysis in the Developing Chick Heart, Robert G. Gourdie, Gang Cheng, Robert P. Thompson, and Takashi Mikawa. Dynamic Labeling Techniques for Fate Mapping, Testing Cell Commitment, and Following Living Cells in Avian Embryos, Diana K. Darnell, Virginio Garcia-Martinez, Carmen Lopez-Sanchez, Shipeng Yuan, and Gary C. Schoenwolf. Cell Lineage Analysis: Videomicroscopy Techniques, Paul J. Heid and Jeff Hardin. Cell Lineage Analysis in Xenopus Embryos, Sally A. Moody. Photoactivatable (Caged) Fluorescein as a Cell Tracer for Fate Mapping in the Zebrafish Embryos, David J. Kozlowski and Eric S. Weinberg. Carboxyfluorescein as a Marker at Both Light and Electron Microscope Levels to Follow Cell Lineage in the Embryo, Dazhong Sun, C. May Griffith, and Elizabeth D. Hay. Part VI. Chimeras. Transplantation Chimeras: Use in Analyzing Mechanisms

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