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Showing 1 - 19 of 19 matches in All Departments
A solid knowledge of anatomy is essential within any number of fields throughout healthcare. A core discipline of all medical degrees, anatomy is generally taught in a series of laboratory sessions and lectures, requiring students to identify a particular organ or structure, explain its function and describe its relation to normal physiology. Students are expected to learn - and practicing clinicians required to remember - an enormous amount of anatomical information. A Visual Guide to Clinical Anatomy is an extraordinary visual reference guide, containing more than 900 high-quality illustrations of the human anatomy. Author and illustrator Robert H. Whitaker draws upon his 30 years of experience as an anatomy demonstrator and lecturer at Cambridge University to present a simple, easy-to-understand approach to both teaching and learning the subject. Each illustration is designed to provide a summary of key anatomical and clinical information of a specific topic or clinical condition. A comprehensive yet user-friendly anatomy resource, this volume: Covers the major areas of human anatomy Provides succinct, clinically relevant information for each illustration Offers clear and accessible synopses of anatomical structures A Visual Guide to Clinical Anatomy is a valuable addition to the bookshelf of any medical student, instructor, surgical trainee, physician, or healthcare practitioner.
Psychiatry Under the Influence investigates the actions and practices of the American Psychiatric Association and academic psychiatry in the United States, and presents it as a case study of institutional corruption.
There are 71 chapters in the book and authors from Australia,
Brazil, Canada, China, Hong Kong, Japan, Mexico, Taiwan and the
United States. The chapters are arranged under seven sections,
which include General Topics in Food Science and Technology; Food
Processing and Engineering; Antioxidants in Foods; Nutrition and
Food Science; Food Safety; Sensory Science of Foods; and Food
Biotechnology. Many of the chapters are exceptional in the quality and depth of science and state-of-the-art instrumentation and techniques used in the experimentation. There is literally a gold mine of new information available in this book, not only for healthful foods for the Pacific Rim but for many other areas as well.
Food and raw material for its production was generally produced via the traditional agriculture. On the other hand, novel chemicals were manufactured in the laboratory or extracted from plant and animal sources. However, as the world population is steadily in creasing, there is a decrease in traditional agriculture productivity and concerns are also expressed over the damage inflicted to the environment and restrictions that might be en forced in food production. At the same time, there is an increasing demand for high qual ity agricultural products as well as for food ingredients related to both the traditional or newly discovered nutrients or phytochemicals. Trends and developments,~n the area of plant biotechnology and bioengineering has allowed manipulation of genes' !lnd/or insertion of new genes, thus production of trans genic plants. Starting from the introduction of agronomic traits, particularly stress resis tance to diverse environmental factors, process and sensory characteristics, food quality and production of novel varieties of plant-based products through genetic engineering, biotechnology is changing the,;agriculture and the concept of production of plant-ba~~d raw materials. Increasing attention is being paid on research for production of plants !pat can provide a wide array of food and non-food products. Perhaps the first non-food pro,d uct that plant biotechnology would achieve is production of large scale custom-designed industrial oils, but the list of chemicals is long, ranging" from oils and specific triacyl glycerols to biopolymers, enzymes, blood components, amo~g others.
This second edition explains the fundamentals of enzymology and describes the role of enzymes in food, agricultural and health sciences. Among other topics, it provides new methods for protein determination and purification; examines the novel concept of hysteresis; and furnishes new information on proteases, oxidases, polyphenol oxidases, lipoxygenases and the enzymology of biotechnology.
Discussing methods of enzyme purification, characterization, isolation, and identification, this book details the chemistry, behavior, and physicochemical properties of enzymes to control, enhance, or inhibit enzymatic activity for improved taste, texture, shelf-life, nutritional value, and process tolerance of foods and food products. The book covers general aspects of enzymology and the biotechnological strategies for enzyme discovery and development. It describes prototypic enzymes of the six chemical types of reactions catalyzed by enzymes, addressing what the enzymes do, their importance to feed and food production, their chemical and biological properties, and measurement of their activity.
Food and raw material for its production was generally produced via the traditional agriculture. On the other hand, novel chemicals were manufactured in the laboratory or extracted from plant and animal sources. However, as the world population is steadily in creasing, there is a decrease in traditional agriculture productivity and concerns are also expressed over the damage inflicted to the environment and restrictions that might be en forced in food production. At the same time, there is an increasing demand for high qual ity agricultural products as well as for food ingredients related to both the traditional or newly discovered nutrients or phytochemicals. Trends and developments,~n the area of plant biotechnology and bioengineering has allowed manipulation of genes' !lnd/or insertion of new genes, thus production of trans genic plants. Starting from the introduction of agronomic traits, particularly stress resis tance to diverse environmental factors, process and sensory characteristics, food quality and production of novel varieties of plant-based products through genetic engineering, biotechnology is changing the,;agriculture and the concept of production of plant-ba~~d raw materials. Increasing attention is being paid on research for production of plants !pat can provide a wide array of food and non-food products. Perhaps the first non-food pro,d uct that plant biotechnology would achieve is production of large scale custom-designed industrial oils, but the list of chemicals is long, ranging" from oils and specific triacyl glycerols to biopolymers, enzymes, blood components, amo~g others.
This Symposium on Modern Methods of Food Analysis was the sev enth in a series of basic symposia, begun in 1976, on topics of major importance to food scientists and food technologists. The Symposium, sponsored jointly by the Institute of Food Technologists and the In ternational Union of Food Science and Technology, was held June 17 and 18, 1983, in New Orleans immediately prior to the 43rd annual 1FT meeting. Like the other six basic symposia, the program brought together outstanding speakers, from biochemistry, chemistry, food science, microbiology and nutrition, who are at the cutting edge of their specialty, and provided a setting where they could interact with each other and with the participants. The Symposium and this book are dedicated to the memory of George F. Stewart (1908-1982) who made so many important contributions to the field of food science, including that of food analysis. Bernard S. Schweigert has documented George F. Stewart's contributions in the Dedication of this book.
Starting from the assumption that all theater is at least implicitly participatory, Professor Whitaker approaches thirteen plays, from Ibsen's Rosmersholm to Beckett's Endgame and Stoppard's Rosencrantz and Guildenstern Are Dead. He asks the reader to commit himself to a variety of points of view--those of witnesses, actors, directors, and characters--as a series of "critical fictions" lead him toward the experience of each play in performance. The author supplies detailed readings of the plays in various modes. The styles of the chapters vary according to the issues dominant in the plays discussed, and the reader experiences simultaneously a sense of approaching the meaning of performance and of gaining a deeper understanding of the play through a subtle and allusive commentary. Originally published in 1977. The Princeton Legacy Library uses the latest print-on-demand technology to again make available previously out-of-print books from the distinguished backlist of Princeton University Press. These editions preserve the original texts of these important books while presenting them in durable paperback and hardcover editions. The goal of the Princeton Legacy Library is to vastly increase access to the rich scholarly heritage found in the thousands of books published by Princeton University Press since its founding in 1905.
Psychiatry Under the Influence investigates the actions and practices of the American Psychiatric Association and academic psychiatry in the United States, and presents it as a case study of institutional corruption.
Starting from the assumption that all theater is at least implicitly participatory, Professor Whitaker approaches thirteen plays, from Ibsen's Rosmersholm to Beckett's Endgame and Stoppard's Rosencrantz and Guildenstern Are Dead. He asks the reader to commit himself to a variety of points of view--those of witnesses, actors, directors, and characters--as a series of "critical fictions" lead him toward the experience of each play in performance. The author supplies detailed readings of the plays in various modes. The styles of the chapters vary according to the issues dominant in the plays discussed, and the reader experiences simultaneously a sense of approaching the meaning of performance and of gaining a deeper understanding of the play through a subtle and allusive commentary. Originally published in 1977. The Princeton Legacy Library uses the latest print-on-demand technology to again make available previously out-of-print books from the distinguished backlist of Princeton University Press. These editions preserve the original texts of these important books while presenting them in durable paperback and hardcover editions. The goal of the Princeton Legacy Library is to vastly increase access to the rich scholarly heritage found in the thousands of books published by Princeton University Press since its founding in 1905.
People who do not believe in God don't want any proof. You can't even talk to them. They don't want to hear it. So here's what you do: Most people who do not believe in God believe in evolution. Show them that evolution cannot possibly explain everything. While there can be no actual proof of God (short of seeing Him in person some day), it IS possible to disprove evolution. Find a few counterexamples, make your friends reconsider their basic assumptions, and they may reconsider the possibility of God. As Spock said on Star Trek, ""If you eliminate the impossible, then whatever remains, however improbable, must be the truth."" For Example... Ask your friend why giraffes are so tall. This is the evolutionist's centerpiece example in their narrative. They'll probably answer, "Because taller giraffes were able get to the high leaves during a drought. Survival of the fittest." This book gives TEN reasons why that answer does NOT explain why giraffes are so tall. The most compelling one is this: Being tall did NOT give an advantage A short giraffe could simply bend down and eat grass. We still have goats, horses, etc., which also did not die out. The problem is that evolutionists DON'T give this fable any thought. They tell each other this anecdote, which lets them hang onto their belief in evolution, which they can use to justify their nonbelief in God. Evolution Does Not Explain Everything Evolution can provide improvements, but it does not explain how things got started. Consider vision. Could a single mutation have caused an eyeball (complete with a lens and a retina), an optic nerve that could keep all the pixels straight, and a brain with pattern recognition? All at once? Very unlikely. These parts could not have arrived one at a time, either. An animal that was missing even one part would not have a system that almost worked; it would have a system that did not work at all. This dead-weight system would not have provided any advantage, and so would not have been carried forward until another mutation could provide the next part. Remember, for the evolutionist, it's all random. They don't believe that there was an Inventor that could design the system, diagnose a problem, and make a correction. Nor can evolution make gradual improvements to sneak up on these
advances: "INSTINCT: " How can a baby's brain be hard-wired to know
how to breathe, suck, and beat its heart? How did babies survive
before these mutations? There's no time to learn these
skills. Show your nonbelieving friends that evolution does not explain it all. Make them reconsider their assumptions. Make them reconsider the possibility of God.
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