Children of the Atomic Bomb is Dr. Yamazaki's account of a lifelong effort to understand and document the impact of nuclear explosions on children, particularly the children conceived but not yet born at the time of the explosions. Assigned in 1949 as Physician in Charge of the United States Atomic Bomb Casualty Commission in Nagasaki, Yamazaki had served as a combat surgeon at the Battle of the Bulge where he had been captured and held as a prisoner of war by the Germans. In Japan he was confronted with violence of another dimension - the devastating impact of a nuclear blast and the particularly insidious effects of radiation on children. Yamazaki's story is also one of striking juxtapositions, an account of a Japanese-American's encounter with racism, the story of a man who fought for his country while his parents were interned in a concentration camp in Arkansas.
Children of the Atomic Bomb is Dr. Yamazaki's account of a lifelong effort to understand and document the impact of nuclear explosions on children, particularly the children conceived but not yet born at the time of the explosions. Assigned in 1949 as Physician in Charge of the United States Atomic Bomb Casualty Commission in Nagasaki, Yamazaki had served as a combat surgeon at the Battle of the Bulge where he had been captured and held as a prisoner of war by the Germans. In Japan he was confronted with violence of another dimension - the devastating impact of a nuclear blast and the particularly insidious effects of radiation on children. Yamazaki's story is also one of striking juxtapositions, an account of a Japanese-American's encounter with racism, the story of a man who fought for his country while his parents were interned in a concentration camp in Arkansas.
The book starts with an introduction to and history of myeloid-derived suppressor cells (MDSCs), followed by a description of their differentiation, their role in the tumour microenvironment and their therapeutic targeting. It closes with an outlook on future developments. In cancer patients, myelopoiesis is perturbed and instead of generating immunogenic myeloid cells (such as dendritic cells, inflammatory macrophages and granulocytes), there is an increase in highly immature MDSCs. These cells are distributed systemically, resulting in general immunosuppression. They also infiltrate tumours, promoting their progression and metastasis by inhibiting the natural anti-tumour immune response. As these cells also interact with classical anti-neoplastic treatments, they have become major therapeutic targets in the pharmaceutical industry and in oncology research.
Academic Writing and Publishing will show academics (mainly in the social sciences) how to write and publish research articles. Its aim is to supply examples and brief discussions of recent work in all aspects of the area in short, sharp chapters. It should serve as a handbook for postgraduates and lecturers new to publishing. The book is written in a readable and lively personal style. The advice given is direct and based on up-to-date research that goes beyond that given in current textbooks. For example, the chapter on titles lists different kinds of titles and their purposes not discussed in other texts. The chapter on abstracts instructs the reader on writing structured abstracts from the start.
Thermal Degradation of Polymeric Materials, Second Edition offers a wealth of information for polymer researchers and processors who require a thorough understanding of the implications of thermal degradation on materials and product performance. Sections cover thermal degradation mechanisms and kinetics, as well as various techniques, such as thermogravimetry in combination with mass spectroscopy and infrared spectrometry to investigate thermal decomposition routes. Other chapters focus on polymers and copolymers, including polyolefins, styrene polymers, polyvinyl chloride, polyamides, polyurethanes, polyesters, polyacrylates, natural polymers, inorganic polymers, high temperature-resistant and conducting polymers, blends, organic-inorganic hybrid materials, nanocomposites, and biocomposites. Finally, other key considerations such as recycling of polymers by thermal degradation, thermal degradation during processing, and modelling, are discussed in detail. Explains mechanisms of polymer degradation, making it possible to understand and predict material behavior at elevated temperatures Offers systematic coverage of each polymer group that is supported by data detailed explanations and critical analysis Investigates thermal decomposition routes in new materials, such as organic-inorganic hybrid materials and polymer nanocomposites
Extensively updated this second edition again brings together a multinational group of distinguished contributors to address every aspect of psychiatric care in the medically ill. This book captures the diversity of the field, whose practitioners -- scholars, physicians, and clinicians of varied backgrounds -- represent a multiplicity of perspectives.
This reference places the latest information at users' fingertips, and a more streamlined format makes it easy to find the exact information quickly and conveniently. Includes access to a companion Web site for additional resources.
With increasing emphasis being placed on screening and early prevention in cancer, this textbook examines the various methods and interventions used in screening in lung cancer, and presents a detailed review of the approaches to prevention and treatment of early disease. It will be of particular interest to lung cancer and respiratory medicine spe
Polymer Science and Engineering: Challenges, Needs, and Opportunities," a report issued in 1981 by the National Research Council's ad hoc Panel on Polymer Science and Engineering gives ample support for the urgent need of increased commitment to basic studies on polymers. Needs and opportunities, mentioned in the Panel's list, included polymerization methods, specialty polymers, high performance materials, and in situ (reaction injection molding) polymerization for direct conversion of monomers/oligomers to useful shapes. Clearly, in all these and several other areas, advances in polymer synthesis are needed. Whether one takes a look at the commodity or specialty polymers area or considers areas of growing needs, such as polymers for the automotive, aerospace, electronics, communications, separations, packaging, biomedical, etc., advances in polymer synthesis are needed. Polymeric materials, as they are constantly being modified and improved, fine-tuned for current and additional needs, and more readily adopted by industry and the public, will have a vastly expanding influence on everyday life. However, lack of long-term support of meaningful size for basic research on all facets of polymer chemistry and engineering, with particular emphasis on making needed advances in polymer synthesis, could well stunt the growth of high techn.ology in our country. Expanding this thought, lack of attention to basic research on polymer synthesis could help foster or insure that we won't have materials with performance profiles to meet requirements of emerging technologies and national needs, in a reasonably economic and timely fashion.
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