From the dawn of life itself, every being that has ever lived owes its existence to the cell.

The discovery of this vital form led to a transformation in medicine but also in our understanding of ourselves - not as bodies or machines but as ecosystems. It has also given us the power to treat a vast array of mortal maladies...and even to create new kinds of human altogether.

Rich with stories of scientists, doctors and the patients whose lives may be saved by their work, The Song of the Cell is a stunning ode to the building blocks of life and the cutting-edge science harnessing their power for the better.

This book summarizes the most recent data on the molecular and cellular mechanisms which determine the unique properties of nerve cells - their ability to differentiate, establish connections to each other, and to form the nervous system with its immense capability for receiving, analysing, and storing information about our external and internal world. The key role of calcium ions in this process is particularly explored, along with nervous system function in aging and neural pathology. The author, based at a high-profile research unit in the Ukraine, is able to draw on significant new research which has not been widely published. Plasticity in nerve cell function will be of interest to researchers and research students in the fields of neurophysiology, cellular physiology, biophysics, and neurochemistry in particular. It will also be of relevance to researchers and medical doctors interested in neuropathology and aging.

Available for the first time with Macmillan's new online learning tool, Achieve, Molecular Cell Biology remains the most authoritative and cutting-edge resource available for the cell biology course. The author team, consisting of world-class researchers and teachers, incorporates medically relevant examples where appropriate to help illustrate the connections between cell biology and health and human disease. Emphasis on experimental techniques that drive advances in biomedical sciences and introduce students to cutting edge research teach students the skills they need for their careers. Achieve, Macmillan's new online learning platform, supports educators and students throughout the full range of instruction, including assets suitable for pre-class preparation, in-class active learning, and post-class study and assessment. Featuring new digital resources to engage students and help them to master cell biology concepts, the pairing of a powerful new platform with outstanding biology content provides an unrivaled learning experience.

Forcourses in cell biology. Connectingfundamental concepts across the world of the cell Known for its strong biochemistry coverage and clear, easy-to-followexplanations and figures, Becker's World of the Cell provides abeautifully illustrated, up-to-date introduction to cell biology concepts,processes, and applications. Informed by years of classroom experience in thecell biology course, the text features accessible and authoritativedescriptions of all major principles, as well as unique scientific insightsinto visualization and applications of cell and molecular biology. With the 10thEdition, the authors guide students to make connections throughout cellbiology, and provide questions that encourage students to practice interpretingand analyzing data. Embedded features in Pearson eText add interactivity,walking students through key figures with narrated explanations. Personalizelearning with Mastering Biology with Pearson eText Mastering (R) empowers youto personalize learning and reach every student. This flexible digital platformcombines trusted content with customizable features so you can teach yourcourse your way. And with digital tools and assessments, students become activeparticipants in their learning, leading to better results. PearsoneText is an easy-to-use digital textbook available within Mastering that letsstudents read, highlight, take notes, and review key vocabulary all in oneplace. If you're not using Mastering, students can purchase Pearson eText ontheir own or you can assign it as a course to schedule readings, view studentusage analytics, and share your own notes with students.

This popular science book systematically introduces major scientific and technological achievements in the field of cells and stem cells, and the conveniences they bring to human life. It covers plant cloning, animal cloning, human cloning, biological missiles, biological drugs, immunocytotherapy, stem cell therapy, stem cell bank, 4D printing, 5D printing, CAR-T technology, and other frontier fields, which reflect the latest progresses and development trends of life sciences. The book is both interesting and rich in information, revealing the magic and mystery of life sciences.

This popular science book systematically introduces major scientific and technological achievements in the field of cells and stem cells, and the conveniences they bring to human life. It covers plant cloning, animal cloning, human cloning, biological missiles, biological drugs, immunocytotherapy, stem cell therapy, stem cell bank, 4D printing, 5D printing, CAR-T technology, and other frontier fields, which reflect the latest progresses and development trends of life sciences. The book is both interesting and rich in information, revealing the magic and mystery of life sciences.

The lymphatic system develops and functions in parallel with the blood circulatory system (termed the "hemovasculature") and accomplishes transport of interstitial fluids, dietary lipids, and reverse transport of cholesterol, immune cells, and antigens-providing a critical homeostatic fluid balance and transmission of immune cells and mediators back to the cardiovascular system. Although the daily flow of lymph (normally 1-2 L/day under unstressed conditions) is far lower than that of daily blood flow (which is 7,500 L/day), without the adequate functioning of the lymphatics, virtually all organs and tissues would acutely suffer many different physical and inflammatory stresses ranging from edema to organ system failure. Although blood and lymphatic vessels often form in anatomic parallels to one another, our knowledge of the workings of the lymphatic system, the fine structure of lymphatic networks, how they function in different organs, and how they are regulated physiologically and immunologically are far from parallel; our knowledge of the lymphatic system still remains at only a tiny fraction of what is understood about the cardiovascular system. Although both the cardiovascular and lymphatic systems are important transport systems, what they transport and how they transport and propel these very different cargoes could not be more dissimilar. This book provides an overview of the history of the discovery (and re-discovery) of the components of the lymphatic system, lymphatic anatomy, physiological functions of lymphatics, molecular features of the lymphatic system, and clinical perspectives involving lymphatics which may be of interest to scientists, clinicians, patients, and the lay public. We provide a current understanding of some of the more important structural similarities and differences between lymphatics and the blood vascular system, their coordinated control by angiogenic and hemangiogenic growth factors and other modulators, the fate and lineage determinants which control lymphatic development, and the roles that lymphatics may play in several different diseases.

Clathrin-mediated endocytosis (CME) is a ubiquitous internalization process in eukaryotic cells. It consists of the formation of an approximately 50-nm diameter vesicle out of a flat membrane. Genetics, biochemistry, and microscopy experiments performed in the last four decades have been instrumental to discover and characterize major endocytic proteins in yeast and mammals. However, due to the highly dynamic nature of the endocytic assembly and its small size, many questions remain unresolved: how are endocytic proteins organized spatially and dynamically? How are forces produced and how are their directions controlled? How do the biochemical activities of endocytic proteins and the membrane shape and mechanics regulate each other? These questions are virtually impossible to visualize or measure directly with conventional approaches but thanks to new quantitative biology methods, it is now possible to infer the mechanisms of endocytosis in exquisite detail. This book introduces quantitative microscopy and mathematical modeling approaches that have been used to count the copy number of endocytic proteins, infer their localization with nanometer precision, and infer molecular and physical mechanisms that are involved in the robust formation of endocytic vesicles.