This book is a comprehensive guide to PET and PET CT and serves as a valuable resource for practicing physicians and residents. The text covers topics ranging from the basic principles of physics, molecular assays, preparation of molecular imaging probes, and biochemistry relevant for PET. Additionally, clinical applications in cancer, cardiovascular diseases, and neurological disorders are thoroughly discussed. U.C.L.A. School of Medicine is recognized as one of the leading PET centers in the world. All of the contributors are U.C.L.A. School of Medicine faculty members and they combined their areas of expertise in order to create the premier reference book on PET. Each chapter provides a complete overview of the topic material and guides the reader through the subject matter. Figures, tables, and solved example problems are integrated into the text. Readers also benefit from the extensive references and suggested reading material.

This book is designed to give the reader a solid understanding of the

physics and instrumentation aspects of PET, including how PET data are collected and formed into an image. Topics include basic physics, detector technology used in modern PET scanners, data acquisition, and 3D reconstruction. A variety of modern PET imaging systems are also discussed, including those designed for clinical services and research, as well as small-animal imaging. Methods for evaluating the performance of these systems are also outlined. The book will interest nuclear medicine students, nuclear medicine physicians, and technologists.

This book is designed to give the reader a solid understanding of the

physics and instrumentation aspects of PET, including how PET data are collected and formed into an image. Topics include basic physics, detector technology used in modern PET scanners, data acquisition, and 3D reconstruction. A variety of modern PET imaging systems are also discussed, including those designed for clinical services and research, as well as small-animal imaging. Methods for evaluating the performance of these systems are also outlined. The book will interest nuclear medicine students, nuclear medicine physicians, and technologists.

Physics in Nuclear Medicine - by Drs. Simon R. Cherry, James A. Sorenson, and Michael E. Phelps - provides current, comprehensive guidance on the physics underlying modern nuclear medicine and imaging using radioactively labeled tracers. This revised and updated fourth edition features a new full-color layout, as well as the latest information on instrumentation and technology. Stay current on crucial developments in hybrid imaging (PET/CT and SPECT/CT), and small animal imaging, and benefit from the new section on tracer kinetic modeling in neuroreceptor imaging. What's more, you can reinforce your understanding with graphical animations online at www.expertconsult.com, along with the fully searchable text and calculation tools. Master the physics of nuclear medicine with thorough explanations of analytic equations and illustrative graphs to make them accessible. Discover the technologies used in state-of-the-art nuclear medicine imaging systems Fully grasp the process of emission computed tomography with advanced mathematical concepts presented in the appendices. Utilize the extensive data in the day-to-day practice of nuclear medicine practice and research. Tap into the expertise of Dr. Simon Cherry, who contributes his cutting-edge knowledge in nuclear medicine instrumentation. Stay current on the latest developments in nuclear medicine technology and methods New sections to learn about hybrid imaging (PET/CT and SPECT/CT) and small animal imaging. View graphical animations online at www.expertconsult.com, where you can also access the fully searchable text and calculation tools. Get a better view of images and line art and find information more easily thanks to a brand-new, full-color layout. The perfect reference or textbook to comprehensively review physics principles in nuclear medicine.

This paper addresses the subject of diversity. The changing demographics in America projects by the year 2000, almost two-thirds of new entrants into the workforce will be women, and 29 percent will be non-white. The key to successful leadership will be an understanding and awareness of diversity in the organization. The purpose of this research is to provide a consolidated source of educational references on diversity. Although this project is narrow in scope and breadth it serves as a point of departure for those attempting to improve their understanding and awareness of the leadership challenges of diversity.Diversity was initially defined as: the different or dissimilar attitudes, values, and way of life between people based on race, religion, color, national origin, economic status, and gender. This definition paved the evolution of diversity around five approaches: (1) the golden rule, (2) assimilation, (3) righting the wrong, (4) culture specific approach, and (5) the multicultural.The prevailing idea on diversity broadens the scope and defines diversity as any mixture of items characterized by differences and similarities. The key here is the inclusion of similarities and synergy created between differences and similarities to achieve an effective workforce reflective of the America society. To assist leaders and mangers in the "diversity challenge," several tools are available. Two such tools are the diversity management process and the diversity paradigm options for action.In conclusion, diversity has made significant improvements in the lives of the American workforce. Although more work lies ahead, diversity's impact on the workforce will continue to evolve with the changing values of our society.