the drama of the front lines.”
-Richard Danzig, former secretary of the navy
The first major bioterror event in the United States-the anthrax attacks in October 2001-was a clarion call for scientists who work with “hot” agents to find ways of protecting civilian populations against biological weapons. In The Demon in the Freezer, his first nonfiction book since The Hot Zone, a #1 New York Times bestseller, Richard Preston takes us into the heart of Usamriid, the United States Army Medical Research Institute of Infectious Diseases at Fort Detrick, Maryland, once the headquarters of the U.S. biological weapons program and now the epicenter of national biodefense.
Peter Jahrling, the top scientist at Usamriid, a wry virologist who cut his teeth on Ebola, one of the world’s most lethal emerging viruses, has ORCON security clearance that gives him access to top secret information on bioweapons. His most urgent priority is to develop a drug that will take on smallpox-and win. Eradicated from the planet in 1979 in one of the great triumphs of modern science, the smallpox virus now resides, officially, in only two high-security freezers-at the Centers for Disease Control in Atlanta and in Siberia, at a Russian virology institute called Vector. But the demon in the freezer has been set loose. It is almost certain that illegal stocks are in the possession of hostile states, including Iraq and North Korea. Jahrling is haunted by the thought that biologists in secret labs are using genetic engineering to create a new superpox virus, a smallpox resistant to all vaccines.
Usamriid went into a state of Delta Alert on September 11 and activated its emergency response teams when the first anthrax letters were opened in New York and Washington, D.C. Preston reports, in unprecedented detail, on the government’s response to the attacks and takes us into the ongoing FBI investigation. His story is based on interviews with top-level FBI agents and with Dr. Steven Hatfill.
Jahrling is leading a team of scientists doing controversial experiments with live smallpox virus at CDC. Preston takes us into the lab where Jahrling is reawakening smallpox and explains, with cool and devastating precision, what may be at stake if his last bold experiment fails.
This edition includes greatly expanded focus on stem cells, including adult and embryonic stem cells and progenitor populations that may soon lead to new tissue engineering therapies for heart disease, diabetes, and a wide variety of other diseases that afflict humanity. This up-to-date coverage of stem cell biology and other emerging technologies is complemented by a series of new chapters on recent clinical experience in applying tissue engineering. The result is a comprehensive textbook that we believe will be useful to students and experts alike.
New to this edition:
*Includes new chapters on biomaterial-protein interactions, nanocomposite and three-dimensional scaffolds, skin substitutes, spinal cord, vision enhancement, and heart valves
*Expanded coverage of adult and embryonic stem cells of the cardiovascular, hematopoietic, musculoskeletal, nervous, and other organ systems
Life is the most extraordinary phenomenon in the known universe; but how did it come to be? Even in an age of cloning and artificial biology, the remarkable truth remains: nobody has ever made anything living entirely out of dead material. Life remains the only way to make life. Are we still missing a vital ingredient in its creation?
Using first-hand experience at the cutting edge of science, Jim Al-Khalili and Johnjoe Macfadden reveal that missing ingredient to be quantum mechanics. Drawing on recent ground-breaking experiments around the world, each chapter in Life on the Edge illustrates one of life's puzzles: How do migrating birds know where to go? How do we really smell the scent of a rose? How do our genes copy themselves with such precision? Life on the Edge accessibly reveals how quantum mechanics can answer these probing questions of the universe.
Guiding the reader through the rapidly unfolding discoveries of the last few years, Al-Khalili and McFadden describe the explosive new field of quantum biology and its potentially revolutionary applications, while offering insights into the biggest puzzle of all: what is life? As they brilliantly demonstrate in these groundbreaking pages, life exists on the quantum edge.
– Winner, Stephen Hawking Medal for Science Communication
The Olympics are the world's most prestigious stage for athletic competition. Fans both casual and hardcore tune in religiously every few years to watch as men and women push themselves to the limits of human performance. But what makes a champion? Is it genetics? Hours of training? A psychological advantage? Of all the athletes who dedicate their lives - and bodies - to achieving that perfect moment of triumph, why will one person or team win out over another? Science has some compelling answers, and in this book, The Science of Sports: Winning in the Olympics, Scientific American explores this topic from various angles. Beginning with Section 1: The Psychology of Winning, the book opens with a look inside the mind of an elite athlete and tackles questions of how to face a rivalry or maintain a positive attitude in the face of defeat. Other sections discuss the sticky issues surrounding genetic advantages and physical prowess, drugs and doping, injury and recovery, and - finally - the latest scientific advice for the rest of us mere mortals to be fit and healthy. You'll find both inspiration and answers in this indispensable book from the editors of Scientific American, the leading authority on science, technology and innovation.
This new edition discusses biological systems that can be analyzed quantitatively, and how advances in the life sciences have been aided by the knowledge of physical or engineering analysis techniques. The volume is organized into 18 chapters encompassing thermodynamics, electricity, optics, sound, solid mechanics, fluid mechanics, and atomic and nuclear physics. Each chapter provides a brief review of the background physics before focusing on the applications of physics to biology and medicine. Topics range from the role of diffusion in the functioning of cells to the effect of surface tension on the growth of plants in soil and the conduction of impulses along the nervous system. Each section contains problems that explore and expand some of the concepts. The text includes many figures, examples and illustrative problems and appendices which provide convenient access to the most important concepts of mechanics, electricity, and optics in the body.
Physics in Biology and Medicine will be a valuable resource for students and professors of physics, biology, and medicine, as well as for applied health workers.Provides practical techniques for applying knowledge of physics to the study of living systemsPresents material in a straight forward manner requiring very little background in physics or biologyIncludes many figures, examples and illustrative problems and appendices which provide convenient access to the most important concepts of mechanics, electricity, and optics in the body
Interested in unraveling the physics of living things? Here's your starting point. Biophysics Demystified is the fast and easy way to understand this fascinating topic.
Written in a step-by-step format, this practical guide begins with an introduction to the science of biophysics, covering biophysical techniques and applications. Next, you'll learn the principles of physics, biology, and chemistry required to understand biophysics, including free energy, entropy, and statistical mechanics. Biomolecules and the forces that influence their structure and conformation are also covered, as are protein, nucleic acid, and membrane biophysics. Detailed examples and concise explanations make it easy to understand the material, and end-of-chapter quizzes and a final exam help reinforce key concepts.
It's a no-brainer! You'll get:Molecular, subcellular, physiological, anatomical, and environmental biophysics The laws of thermodynamics as they apply to biophysical systems Forces affecting conformation in biological molecules The composition and structure of carbohydrates, lipids, proteins, and nucleic acids The fluid mosaic model
Simple enough for a beginner, but challenging enough for an advanced student, Biophysics Demystified makes this interdisciplinary subject easy to master.
One of the most diverse of modern scientific disciplines, biophysics applies methods and technologies from physics to the study of biological systems and phenomena, from the human nervous system to soil erosion to global warming. What are the best options for satisfying the world's growing energy demands? How can we feed the world's growing population? How can we contain, or reverse, global warming? How can we vouchsafe a plentiful supply of potable water for future generations? These are among the critical questions to which biophysicists work to provide answers.Biophysics courses are increasingly taken by students of biology, physics, chemistry, biochemistry, physiology, statistics, bioengineering, neuroscience, computer science, pharmacology, agriculture,and many more Provides a friendly, unintimidating overview of the material covered in a typical college-level biophysics course A one-stop reference, course supplement and exam preparation tool for university students currently enrolled in an introductory biophysics courses An indispensable resource for those studying the natural sciences, biological sciences, and physics, as well as math, statistics,computer science, pharmacology and many other disciplines The current job market for people well versed in biophysics is very strong, and biophysics is currently listed as one of the fast-growing occupations in the North America
The handbook begins with a series of historical vignettes of pioneers from the last two centuries. It also presents the fundamentals of physics and biology as applied to photomedicine. It next examines conditions and diseases caused by light, including skin cancer, dermatoses, and immunosuppression.
The remainder of the book focuses on the most important clinical therapeutic applications of different kinds of light that vary in both wavelength and intensity. The book discusses ultraviolet phototherapy for skin diseases and infections and presents the basic science of photodynamic therapy and its use in cancer therapy and other medical specialties. It then covers mechanistic studies and clinical applications of low-level laser (light) therapy as well as the use of high power or surgical laser therapy in specialties, such as dentistry and dermatology. The book concludes with a collection of miscellaneous types of phototherapy.
This concise introductory paperback surveys and relates basic physics to living systems. It discusses biological systems that can be analyzed quantitatively, and how advances in the life sciences have been aided by the knowledge of physical or engineering analysis techniques.
This text is designed for premed students, doctors, nurses, physiologists, or other applied health workers, and other individuals who wish to understand the nature of the mechanics of our bodies.
- Provides practical techniques for applying knowledge of physics to the study of living systems
- Presents material in a straight forward manner requiring very little background in physics or biology
- Includes many figures, examples and illustrative problems and appendices which provide convenient access to the most important concepts of mechanics, electricity, and optics
As advances in algorithms and computer technology have bolstered the digital signal processing capabilities of real-time sonar, radar, and non-invasive medical diagnostics systems, cutting-edge military and defense research has established conceptual similarities in these areas. Now civilian enterprises can use government innovations to facilitate optimal functionality of complex real-time systems. Advanced Signal Processing details a cost-efficient generic processing structure that exploits these commonalities to benefit commercial applications.
Learn from a Renowned Defense Scientist, Researcher, and Innovator
The author preserves the mathematical focus and key information from the first edition that provided invaluable coverage of topics including adaptive systems, advanced beamformers, and volume visualization methods in medicine. Integrating the best features of non-linear and conventional algorithms and explaining their application in PC-based architectures, this text contains new data on:
Advances in biometrics, image segmentation, registration, and fusion techniques for 3D/4D ultrasound, CT, and MRI
Fully digital 3D/ (4D: 3D+time) ultrasound system technology, computing architecture requirements, and relevant implementation issues
State-of-the-art non-invasive medical procedures, non-destructive 3D tomography imaging and biometrics, and monitoring of vital signs
Cardiac motion correction in multi-slice X-ray CT imaging
Space-time adaptive processing and detection of targets interference-intense backgrounds comprised of clutter and jamming
With its detailed explanation of adaptive, synthetic-aperture, and fusion-processing schemes with near-instantaneous convergence in 2-D and 3-D sensors (including planar, circular, cylindrical, and spherical arrays), the quality and illustration of this text’s concepts and techniques will make it a favored reference.
Developed at MIT in collaboration with award-winning high school teachers, BioBuilder teaches the foundational ideas of the emerging synthetic biology field, as well as key aspects of biological engineering that researchers are exploring in labs throughout the world. These lessons will empower teachers and students to explore and be part of solving persistent real-world challenges.Learn the fundamentals of biodesign and DNA engineeringExplore important ethical issues raised by examples of synthetic biologyInvestigate the BioBuilder labs that probe the design-build-test cycleTest synthetic living systems designed and built by engineersMeasure several variants of an enzyme-generating genetic circuitModel "bacterial photography" that changes a strain’s light sensitivityBuild living systems to produce purple or green pigmentOptimize baker’s yeast to produce ?-carotene
Each chapter of the book investigates a facet of the physical world, including the drag on small projectiles; the importance of diffusion and convection; the size-dependence of acceleration; the storage, conduction, and dissipation of heat; the relationship among pressure, flow, and choice in biological pumps; and how elongate structures tune their relative twistiness and bendiness. Vogel considers design-determining factors all too commonly ignored, and builds a bridge between the world described by physics books and the reality experienced by all creatures. Glimpses of Creatures in Their Physical Worlds contains a wealth of accessible information related to functional biology, and requires little more than a basic background in secondary-school science and mathematics.
Drawing examples from creatures of land, air, and water, the book demonstrates the many uses of biological diversity and how physical forces impact biological organisms.
Every brain begins as a female brain. It only becomes male eight weeks after conception, when excess testosterone shrinks the communications center, reduces the hearing cortex, and makes the part of the brain that processes sex twice as large.
Louann Brizendine, M.D. is a pioneering neuropsychiatrist who brings together the latest findings to show how the unique structure of the female brain determines how women think, what they value, how they communicate, and whom they’ll love. Brizendine reveals the neurological explanations behind why
• A woman remembers fights that a man insists never happened
• A teen girl is so obsessed with her looks and talking on the phone
• Thoughts about sex enter a woman’s brain once every couple of days but enter a man’s brain about once every minute
• A woman knows what people are feeling, while a man can’t spot an emotion unless somebody cries or threatens bodily harm
• A woman over 50 is more likely to initiate divorce than a man
Women will come away from this book knowing that they have a lean, mean communicating machine. Men will develop a serious case of brain envy.
This book provides a roadmap to the broad and varied career development opportunities in bioengineering, biotechnology, and related fields. Eminent practitioners lay out career paths related to academia, industry, government and regulatory affairs, healthcare, law, marketing, entrepreneurship, and more.
Lifetimes of experience and wisdom are shared, including "war stories," strategies for success, avoidance of common pitfalls, and discussions of the authors’ personal views and motivations. Career Development in Bioengineering and Biotechnology is an indispensable guide to some of the most exciting career and professional growth opportunities in science, engineering, and beyond, and a "must read" for anyone interested in a career related to this burgeoning field.
From the Foreword by U.S. National Medal of Science Laureate and Institute Professor Robert Langer, Massachusetts Institute of Technology: "This book provides a wealth of information and should serve as an excellent resource...The editors have gone to great effort to discuss a variety of critical topics in the burgeoning areas of bioengineering and biotechnology."
From the Introduction by Dr. Bruce Alberts, President Emeritus of the U.S. National Academy of Sciences and Co-chair of the InterAcademy Council: "I am very impressed with the enormous dedication and skill that created this major, highly-original contribution – I know of nothing like it."
From the Editorial by Dr. Joachim Nagel, President, International Union for Physical and Engineering Sciences in Medicine, and past president of the International Federation for Medical and Biological Engineering: "This book provides all the answers and can be highly recommended as the ultimate guide to anyone interested in bioengineering and biotechnology. The book arrives at a crucial time, and catapults bioengineering and biotechnology to the forefront of disciplines and to a rightly held pinnacle of inspiration for engineers, scientists, and technologists."
From the Afterword by Dr. Shu Chien, President, Biomedical Engineering Society and past president of the American Physiological Society and of the American Institute of Medical and Biological Engineering: "...this is truly an outstanding book that is the first of its kind...certainly a pioneering contribution."
Praise for the Book
"Bioengineering and Biotechnology are emerging as distinct disciplines amid the biological revolution and during a period of rapid globalization. These interesting times offer us unprecedented opportunities for professional and personal growth. This book covers many important areas of opportunity, including entrepreneurship, finance, law, and education, with a global perspective. The legacy of our times will include how well we used our rapidly advancing technologies to improve the world around us. This book provides a roadmap for the contributions of Bioengineering and Biotechnology in this quest."
-James E. Moore, PhD, Texas A&M University
"This book will be essential reading for all those seeking career guidance in bioengineering and biotechnology."
-Tony Bradshaw, PhD, Director bioProcessUK - BioIndustry Association (BIA), Chairman, The Royal Academy of Engineering/BIA Life Scientists' Career Seminars
"...the topics [are] quite extensive covering definitions, core curriculum, career opportunities, including a wide range of alternative career pathways as well as social and ethical issues. The material covered is unlike any of the standard publications related to these fields of activity... [the book] can be read at different stages of one's career."
-Joseph D. Bronzino, PhD, Trinity College
"...once I started reading it, [I] could not put it down. In less than three days, I read it all, absorbing the stories and details as if I was consummed by watching a high action movie... The breath and depth of the wisdom is phenomenal, and the stories shared by the writers are moving, inspiring, and shine of intelligence in seizing one's own passion and talents and turning them into stellar professional careers."
-Nathalie Gosset, MS, MBA, Head of Marketing, Alfred Mann Institute for Biomedical Engineering, University of Southern California
"This is a functional book with immediate impact, and is very helpful to those who need and desperately want help in making a career choice."
- Jonathan Newman, Graduate Student in Biomedical Engineering, Georgia Institute of Technology, USA
"This is an exciting undertaking and very well thought through and balanced. I enjoyed very much reading the chapters I have reviewed. Congratulations to all contributors and the editors of this book."
- Gudrun Zahlmann, PhD, Director of Business Development, Siemens Medical Systems, Germany
"I am very excited about this book. As a bioengineering educator, I am always looking for information that can provide guidance for students as they prepare for their careers. The contributors in this book are so enthusiastic about their careers that many of the chapters made me want to switch careers on the spot! I believe that engineering students do not receive enough guidance on alternative career paths. This book will very much help fill the void."
- Judy Cezeaux, PhD, Professor of Biomedical Engineering, Western New England College, Massachusetts, USA
The volume is intended for graduate-level biology students as well as researchers who wish to gain a better understanding of applied bioinformatics and who wish to use bioinformatics technologies to assist in their research. The volume would also be of value to bioinformatics developers, particularly those from a computing background, who would like to understand the application of computational tools for biological research. Each chapter would include a comprehensive introduction giving an overview of the fundamentals, aimed at introducing graduate students and researchers from diverse backgrounds to the field and bring them up-to-date on the current state of knowledge. To accommodate the broad range of topics in applied bioinformatics, chapters have been grouped into themes: gene and genome analysis, molecular genetic analysis, gene expression analysis, protein and proteome analysis, metabolome analysis, phenome data analysis, literature mining and bioinformatics tool development. Each chapter and theme provides an introduction to the biology behind the data describes the requirements for data processing and details some of the methods applied to the data to enhance biological understanding.
Erik Seedhouse is eminently qualified to describe the effects of large accelerations on the body. In addition to being the author of several previously published Springer Praxis books, he has developed astronaut-training protocols and is the training director for Astronauts for Hire (A4H). He is also the Canadian Forces’ High Risk Acceleration Training Officer.
Each chapter includes a discussion of recent technological developments and the biological effects of the imaging modality. End-of-chapter problem sets, lists of relevant references, and suggested further reading are presented for each technique.X-ray imaging, including CT and digital radiographyRadionuclide imaging, including SPECT and PETUltrasound imagingMagnetic resonance imaging
In biomedical research, because of a dramatic increase in productivity, immunocytochemistry has emerged as a major technique. The proposed book will provide the first practical guide to planning, performing, and evaluating immunocytochemical experiments.
In today’s graduate education the emphasis is on doing research and not on formal class work. Graduate students therefore lack the background in many essential techniques necessary to perform research in fields in which they were not trained. As director of a university core microscopy facility which sees students and faculty from dozens of laboratories each year, Dr. Burry has surmised the vast majority of these novice microscope users need considerable help. In an attempt to educate users, Dr. Burry has initiated immunocytochemistry seminars and workshops which serve to train people in this powerful research tool. The proposed book is an outgrowth of these presentations and conversations with, by now, hundreds of people who have asked for help.
The philosophy which separates this book from other books in this field is that it is practical, rather than academic. In looking at other important immunocytochemistry titles, the predominant orientation is academic, with the author attempting to comprehensively discuss the topic. For example, one book with sample preparation lists ten fixatives which can be used; however, only two such fixatives are commonly used today. In this particular title, the detailed discussion of old methods might be seen as important in establishing the author as an expert. By contrast, the approach for Burry’s book would be to discuss methods based on what works in animal research laboratories today, and focus only on the most productive methods.
An additional distinction with this proposed book is the focus on animal research and not human pathology. There is a certification program for pathology technicians which requires them to learn a set body of material based on processing human tissue for examination by a pathologist. Many of the books on immunocytochemistry aim at this large pathology user base. Due to historical reasons, pathology laboratories process human tissues in a specific way and embed the tissue in paraffin, as has been done for over a century. In the last ten years, the power of immunocytochemistry in clinical diagnosis has become clear and has accordingly been adapted to pathology. However, the extensive processing needed for paraffin sections is not needed if the tissues are from research animals. Processing for animal-based tissues takes about a third of the time and results in higher quality images. The focus of this book is on processing these animal research tissues for immunocytochemistry. Today, there are no technique books which are aimed at this user base.
As a subject matter expert in the area of the proposed book, Dr. Burry will make recommendations and offer opinions. Because this field is new and is emerging, there are numerous advantages of specific methods over other, more generalized methods. The purpose of this book is to show a novice how to do immunocytochemistry without engaging in a discussion of possible advanced methods. For the advanced user, there are several good books which discuss the unusual methods, yet for the novice there are currently none.
Main Author :
Richard W. Burry, The Ohio State University (United States).
The Outline of the Book :
Each chapter supplies a set of important principals and steps necessary for good immunocytochemistry. The information is distilled down to include only the most important points and does not attempt to cover infrequently used procedures or reagents. At the end of most chapters is a section on trouble-shooting many of the common problems using the Sherlock Holmes method. Each chapter also includes specific protocols which can be used. The goal of each chapter is to present the reader with enough information to successfully design experiments and solve many of the problems one may encounter. Using immunocytochemical protocols without the understanding of their workings is not advised, as the user will need to evaluate his or her results to determine whether the results are reliable. Such evaluation is extremely important for users who need reliable images which will clearly answer important scientific questions.
Definitions (immunocytochemistry and immunohistochemistry)
Scope: animal research and not human pathology, paraffin sections, epitope retrieval, or immunohistochemistry
Focus: fluorescence and enzyme detection
Why do immunocytochemistry?
Immunocytochemistry "individual study" rather than "population study"
Example of a two-label experiment
What is included in these chapters?
Overview of the theory
Background with enough information to help solve common problems.
Advantages and disadvantages of different options
Opinions and suggestions
2. Fixation and Sectioning
Chemistry of fixation
Denaturing vs cross-linking fixatives
Application of fixative
Perfusion, drop-in, cultures, fresh-frozen
Selection of sample section type
Rapid freezing, cryostat, freezing microtome, vibratome
Storage of tissue
Isoforms, structure, reactivity
Polyclonal vs monoclonal
Antibodies as reagents
Antibody specificity and sources
Storage and handling
4. Labels for antibodies
Fluorescence, enzymes and particulates
Fluorescent labels - four generations
Selecting enzymes vs. fluorescence
Selecting a label- advantages and disadvantages
5. Methods of applying antibodies
Antibody amplification methods
6. Blocking and Permeability
Theory of blocking
Theory of detergents
7. Procedure- Single primary antibody
Sample, fixation, sectioning
8. Multiple primary antibodies - primary antibodies of different species
9. Multiple primary antibodies-primary antibodies of same species
Wide-field fluorescence microscope
Bright field—enzyme chromogen
Size, intensity, and pixels
Manipulation—what is ethical?
11. Planning and Troubleshooting
Scheme for discussion-making in planning experiments
Case studies with Sherlock Holmes detective work
12. So you want to do electron microscopic ICC?
Criteria in decision-making
Summary of the two techniques
Intended for science and engineering students with one year of introductory physics background, this textbook presents the medical applications of fundamental principles of physics to students who are considering careers in medical physics, biophysics, medicine, or nuclear engineering. It also serves as an excellent reference for advanced students, as well as medical and health researchers, practitioners, and technicians who are interested in developing the background required to understand the changing landscape of medical science. Practice exercises are included and solutions are available separately in an instructor's manual.Complete discussion of the fundamental physical principles underlying modern medicineAccessible exploration of the physics encountered in a typical visit to a doctorPractice exercises are included and solutions are provided in a separate instructor’s manual (available to professors)A companion website (modernphysicsinmedicine.com) presents supplementary materials
An Introduction to Systems Biology: Design Principles of Biological Circuits builds a solid foundation for the intuitive understanding of general principles. It encourages the reader to ask why a system is designed in a particular way and then proceeds to answer with simplified models.
Why do you fall in love with one person rather than another? In this fascinating and informative book, Helen Fisher, one of the world's leading experts on romantic love, unlocks the hidden code of desire and attachment. Each of us, it turns out, primarily expresses one of four broad personality types—Explorer, Builder, Director, or Negotiator—and each of these types is governed by different chemical systems in the brain. Driven by this biology, we are attracted to partners who both mirror and complement our own personality type.
Until now the search for love has been blind, but Fisher pulls back the curtain and reveals how we unconsciously go about finding the right match. Drawing on her unique study of 40,000 men and women, she explores each personality type in detail and shows you how to identify your own type. Then she explains why some types match up well, whereas others are problematic. (Note to Explorers: be prepared for a wild ride when you hitch your star to a fellow Explorer!) Ultimately, Fisher's investigation into the complex nature of romance and attachment leads to astonishing new insights into the essence of dating, love, and marriage.
Based on entirely new research—including a detailed questionnaire completed by seven million people in thirty-three countries—Why Him? Why Her? will change your understanding of why you love him (or her) and help you use nature's chemistry to find and keep your life partner.
Over 800 problems (a 44% increase from the third edition) are included to test the student's understanding and to provide additional biological examples. A solutions manual is available to instructors. Each chapter has an extensive list of references as well as useful bibliographies for further reading. Intermediate Physics for Medicine and Biology is also ideal for self study and as a reference for workers in medical and biological research.
KEY FEATURES:Provides an excellent background in physics for physicians, biomedical engineers, and biologists Includes a new chapter on sound and ultrasound and presents stochastic processes as an integral part of biological systems Emphasizes applications of physics to biomedicine rather than molecular biophysics Contains numerous problems and exercises for course use and as a reference for self study
Covering mitochondria, bacteria and chloroplasts, the fourth edition of Bioenergetics provides a clear and comprehensive account of the chemiosmotic theory and its many applications. The figures have been carefully designed to be memorable and to convey the key functional and mechanistic information. Written for students and researchers alike, Bioenergetics is the most well-known, current and respected text on chemiosmotic theory and membrane bioenergetics available.BMA Medical Book Awards 2014-Highly Commended, Basic and Clinical Sciences,2014,British Medical AssociationChapters are now divided between three interlocking sections: basic principles, structures and mechanisms, and mitochondrial physiology. Covers new advances in the structure and mechanism of key bioenergetic proteins, including complex I of the respiratory chain and transport proteins.Details cellular bioenergetics, mitochondrial cell biology and signal transduction, and the roles of mitochondria in physiology, disease and aging.Offers readers clear, visual representation of structural concepts through full colour figures throughout the book.
The book contains 17 new and updated chapters covering the fundamentals and latest advances in the area, and includes four appendices, 450 figures (60 available in color on the companion website), and almost 1,500 references. In addition to the continual influx of readers entering the field of ultrasound worldwide who need the broad grounding in the core technologies of ultrasound, this book provides those already working in these areas with clear and comprehensive expositions of these key new topics as well as introductions to state-of-the-art innovations in this field.Enables practicing engineers, students and clinical professionals to understand the essential physics and signal processing techniques behind modern imaging systems as well as introducing the latest developments that will shape medical ultrasound in the futureSuitable for both newcomers and experienced readers, the practical, progressively organized applied approach is supported by hands-on MATLAB® code and worked examples that enable readers to understand the principles underlying diagnostic and therapeutic ultrasoundCovers the new important developments in the use of medical ultrasound: elastography and high-intensity therapeutic ultrasound. Many new developments are comprehensively reviewed and explained, including aberration correction, acoustic measurements, acoustic radiation force imaging, alternate imaging architectures, bioeffects: diagnostic to therapeutic, Fourier transform imaging, multimode imaging, plane wave compounding, research platforms, synthetic aperture, vector Doppler, transient shear wave elastography, ultrafast imaging and Doppler, functional ultrasound and viscoelastic models
Nessa Carey, a leading epigenetics researcher, connects the field’s arguments to such diverse phenomena as how ants and queen bees control their colonies; why tortoiseshell cats are always female; why some plants need cold weather before they can flower; and how our bodies age and develop disease. Reaching beyond biology, epigenetics now informs work on drug addiction, the long-term effects of famine, and the physical and psychological consequences of childhood trauma. Carey concludes with a discussion of the future directions for this research and its ability to improve human health and well-being.
Beginning with simple theoretical models and experimental techniques, the book develops the complete repertoire of theoretical principles and experimental techniques necessary for understanding and implementing the most sophisticated NMR experiments.
Important new techniques and applications of NMR spectroscopy have emerged since the first edition of this extremely successful book was published in 1996. This updated version includes new sections describing measurement and use of residual dipolar coupling constants for structure determination, TROSY and deuterium labeling for application to large macromolecules, and experimental techniques for characterizing conformational dynamics. In addition, the treatments of instrumentation and signal acquisition, field gradients, multidimensional spectroscopy, and structure calculation are updated and enhanced.
The book is written as a graduate-level textbook and will be of interest to biochemists, chemists, biophysicists, and structural biologists who utilize NMR spectroscopy or wish to understand the latest developments in this field.Provides an understanding of the theoretical principles important for biological NMR spectroscopyDemonstrates how to implement, optimize and troubleshoot modern multi-dimensional NMR experimentsAllows for the capability of designing effective experimental protocols for investigations of protein structures and dynamicsIncludes a comprehensive set of example NMR spectra of ubiquitin provides a reference for validation of experimental methods
Junk DNA can play vital and unanticipated roles in the control of gene expression, from fine-tuning individual genes to switching off entire chromosomes. Its function has forced scientists to revisit the very meaning of the word “gene” and has engendered a bitter battle over whether or not this genomic “nonsense” is the source of human biological complexity. Drawing on her experience with leading investigators in Europe and North America, Nessa Carey provides a clear and compelling introduction to junk DNA and its critical involvement in phenomena as diverse as genetic diseases, viral infections, sex determination in mammals, disease treatments, and evolution. We are only now unlocking the secrets of junk DNA, and Carey’s book is an indispensable resource for navigating the codes and controversies of this fast-growing and hotly disputed field.
Many will be amazed to learn that all these questions, and many more, can be answered by a single point of discussion—mitochondria and bioenergetics. This legendary saga began over two billion years ago, when one bacterium entered another without being digested, ultimately creating the first mitochondrion.
Since then, for life to exist beyond single-celled bacteria, it’s the mitochondria that are responsible for this life-giving energy. Yet, current research has also revealed a dark side; many seemingly unconnected degenerative diseases have their roots in dysfunctional mitochondria. Modern research, however, has also endowed us with the knowledge on how to optimize its function, which is of critical importance to our health and longevity. By reading this book, you are about to dive into this epic story, and learn how to add years to your life, and life to your years.
Free Radicals in Medicine
Radicals in vivo and in Model Systems, and their Study by Spin Trapping
In vivo EPR, including Oximetry and Imaging
Time Domain EPR at Radio Frequencies
EPR of Copper Complexes: Motion and Frequency Dependence
Time Domain EPR and Electron Spin Echo Envelope Modulation
Medical Applications of Mass Spectrometry addresses the key issues in the medical applications of mass spectrometry at the level appropriate for the intended readership. It will go a long way to help the utilization of mass spectrometry in medicine.
The book comprises five parts. A general overview is followed by a description of the basic sampling and separation methods in analytical chemistry. In the second part a solid foundation in mass spectrometry and modern techniques of data analysis is presented. The third part explains how mass spectrometry is used in exploring various classes of biomolecules, including proteins and lipids. In the fourth section mass spectrometry is introduced as a diagnostic tool in clinical treatment, infectious pathogen research, neonatal diagnostics, cancer, brain and allergy research, as well as in various fields of medicine: cardiology, pulmonology, neurology, psychiatric diseases, hemato-oncology, urologic diseases, gastrointestinal diseases, gynecology and pediatrics. The fifth part covers emerging applications in biomarker discovery and in mass spectrometric imaging.
* Provides a broad look at how the medical field is benefiting from advances in mass spectrometry.
* Guides the reader from basic principles and methods to cutting edge applications.
* There is NO comparable book on the market to fill this fast growing field.
Introducing the diverse and complex field of biophysics in an academically rigorous but in-teresting way poses daunting challenges. Indeed, the course has undergone many transforma-tions and has tried on many styles: seminar/journal club, lecture/lab, and just plain didactic lec-ture formats. These, however, have achieved limited success, because they either assume a strong mathematics/physical-science background or reduce the physical science to a pedestrian level of knowledge, or demand that students trudge along with the expert researchers. None have attracted the interest of biology, physiology, or medical students, who must search for the biological meaning within biophysics.
One major obstacle to developing an attractive but scholarly course centers on the balance between formalism and perspective. Each biophysics technique requires a mastery of a chal-lenging set of physical-science/mathematics formalism. Yet even with mastery the reader may still not gain a biomedical perspective. How will these biophysical techniques help clarify the complex issues in biology? Moreover, how will the course deal with biomedical students’ reluc-tance to overcome the imposing physical-science/mathematical formalism in order to gain new perspectives on biology?
These considerations have given rise to the series Handbook of Modern Biophysics. The books in this series will bring current biophysics topics into focus and expand as the field of biophysics expands, so that biology and physical-science students or researchers can learn fun-damental concepts and apply new biophysics techniques to address biomedical questions. How-ever, the chapter structure will recognize the demand for explicating the conceptual framework of the underlying physics formalism and for casting perspectives on the biomedical applica-tions. Each chapter will have a bipartite structure: the first part establishes the fundamental physics concepts and describes the instrumentation or technique, while the second illustrates current applications in addressing complex questions in biology. With the addition of problem sets, further study, and references, the interested reader will be able to further explore the ideas presented.
In the first volume, Fundamental Concepts in Biophysics, the authors lay down a foundation for biophysics study. Rajiv Singh opens the book by pointing to the central importance of "Mathematical Methods in Biophysics." William Fink follows with a discussion on "Quantum Mechanics Basic to Biophysical Methods." Together, these two chapters establish some of the principles of mathematical physics underlying many biophysics techniques. Because computer modeling forms an intricate part of biophysics research, Subhadip Raychaudhuri and colleagues introduce the use of computer modeling in "Computational Modeling of Receptor–Ligand Bind-ing and Cellular Signaling Processes." Yin Yeh and coworkers bring to the reader’s attention the physical basis underlying the common use of fluorescence spectroscopy in biomedical re-search in their chapter "Fluorescence Spectroscopy." Electrophysiologists have also applied biophysics techniques in the study of membrane proteins, and Tsung-Yu Chen et al. explore stochastic processes of ion transport in their "Electrophysiological Measurements of Membrane Proteins." Michael Saxton takes up a key biophysics question about particle distribution and behavior in systems with spatial or temporal inhomogeneity in his chapter "Single-Particle Tracking." Finally, in "NMR Measurement of Biomolecule Diffusion," Thomas Jue explains how magnetic resonance techniques can map biomolecule diffusion in the cell to a theory of respiratory control .
This book thus launches the Handbook of Modern Biophysics series and sets up for the reader some of the fundamental concepts underpinning the biophysics issues to be presented in future volumes.