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In response to the growing global health challenge in the fight against cancer, there is now a greater need for radiation oncology health professionals across institutions to collaborate and be more globally engaged. Emerging Models for Global Health in Radiation Oncology is a response to the need for a book that comprehensively covers the important and emerging field of radiation oncology. The recent World Health Organization (WHO) Cancer Report describes the growing global burden of cancer as alarming, a major obstacle to human development and well-being, with a growing annual economic cost of ca. US$1.16 trillion. The report also highlights major global cancer disparities, and these major disparities in cancer deaths are in part a reflection of poignant underlying differences in radiation oncology services. In parallel with this, there has been a major recent upsurge in radiation oncology global health interest and a common issue expressed at global health summits, seminars, and symposia is that people want to participate in global health but do not know how. This insightful book highlights the emerging models for global radiation oncology, and serves as a useful resource to facilitate participation and greater effective collaborative global cancer care, research, education, and outreach. It is suitable for researchers, students, health professionals, and anyone interested in the global oncology community.
This is the second, completely updated edition of a comprehensive book in which many of the world’s leading lung cancer specialists discuss the recent advances in the radiation oncology of lung cancer and reflect on the latest research findings. The first three sections cover the basic science of lung cancer, clinical investigations, including histology and staging, and a wide range of fundamental treatment considerations. Current treatment strategies for small cell and non-small cell lung cancer are then explained and evaluated in detail, with due attention to novel approaches that promise further improvements in outcome. The various types of treatment-related toxicity are discussed, and quality of life studies and prognostic factors are also considered. After evaluating the latest technological and biological advances, including IMRT, IMAT, cyber knife treatment, and tomotherapy, the book concludes by thorough consideration of specific aspects of clinical research in lung cancer.
Stereotactic body radiation therapy (SBRT) has emerged as an important innovative treatment for various primary and metastatic cancers. This book provides a comprehensive and up-to-date account of the physical/technological, biological, and clinical aspects of SBRT. It will serve as a detailed resource for this rapidly developing treatment modality. The organ sites covered include lung, liver, spine, pancreas, prostate, adrenal, head and neck, and female reproductive tract. Retrospective studies and prospective clinical trials on SBRT for various organ sites from around the world are examined, and toxicities and normal tissue constraints are discussed. This book features unique insights from world-renowned experts in SBRT from North America, Asia, and Europe. It will be necessary reading for radiation oncologists, radiation oncology residents and fellows, medical physicists, medical physics residents, medical oncologists, surgical oncologists, and cancer scientists.
This book provides a clinical insight into image-guided radiation therapy (IGRT) for prostate cancer. It starts by setting the clinical scene, discussing immobilisation and standard IGRT practice and then considering important developments like IGRT with non-ionising radiation, adaptive radiotherapy, particle therapy, margins, hypofractionation, clinical outcomes, AI and training. Good IGRT requires both technical and clinical focus. So, in complement to our first study guide on IGRT, this book now brings together key, clinical insights into IGRT for Prostate Cancer patients, with a view to helping the professional learn more about ‘how-to’ undertake IGRT for these patients more accurately, effectively and safely, throughout the whole course of a patient’s treatment with radiation. This clinical insight guide will be of interest to newly qualified radiation therapists, therapeutic radiographers, medical dosimetrists, medical physicists, radiotherapy physicists and clinical oncologists. It will also be of use for trainees and can be used alongside continuing competency and clinical training within real clinical departments and radiation therapy centres worldwide. This is the first in a forthcoming series of clinical insights, each tackling a different treatment area. Further areas in the series will be: Head and Neck; Thorax; Breast; Pelvis; and the Brain. Key Features: • Internationally applicable, clinically focused, up-to-date and evidence based. · Accompanied by suitable electronic multimedia resources. · Authored by experts with decades of experience of pioneering electronic portal imaging and IGRT in clinical practice, pedagogic research and substantial experience of teaching/supervising students, trainees and qualified therapists/medical physicists at bachelors, postgraduate and doctoral levels. Mike Kirby and Kerrie-Anne Calder are well-respected authors and radiotherapy professionals, who have worked in radiotherapy physics/radiotherapy clinical and academic practice for nearly 35 years and 25 years respectively. Mike Kirby is a Senior Lecturer in Radiotherapy Physics at the University of Liverpool, UK, and an Honorary Lecturer at the University of Manchester, UK. He holds graduate and postgraduate qualifications in medical physics and has in total over 200 books, papers, oral and poster presentations to his name in the field of radiotherapy. Dr. Kirby holds professional membership of the Institute of Physics and Engineering in Medicine, the American Association of Physicists in Medicine, the American Society for Radiation Oncology, the European Society for Radiotherapy and Oncology and the British Institute of Radiology, is a Fellow of the Higher Education Academy and the British Institute of Radiology in the UK. Kerrie-Anne Calder is a Lecturer at the University of Liverpool, UK, where she educates undergraduate and post graduate students in many aspects of radiotherapy with a special interest and role in imaging training. Kerrie-Anne has graduate and postgraduate qualifications in radiotherapy, education and academic practice, is a member of the Society and College of Radiographers, and is a Fellow of the Higher Education Academy in the UK. She was a clinical and professional lead in IGRT (on-treatment verification imaging) within the NHS in the UK for over ten years.
Accelerated partial breast irradiation (APBI) is being rapidly introduced into the clinical management of early breast cancer. APBI, in fact, encompasses a number of different techniques and approaches that include brachytherapy, intraoperative, and external beam techniques. There is currently no single source that describes these techniques and their clinical implementation. This text is a concise handbook designed to assist the clinician in the implementation of APBI. This includes a review of the principles that underlie APBI, a practical and detailed description of each technique for APBI, a review of current clinical results of APBI, and a review of the incidence and management of treatment related complications.
This book is a practical, up-to-date guide to the treatment of patients with brain and spinal tumors. Leading experts in the field explain treatment techniques in detail, highlighting key considerations in the use of external beam radiation therapy, intensity-modulated radiation therapy, particle therapy, radiosurgery, and stereotactic body radiation therapy. Specific recommendations are described for different tumor types, and helpful information provided on other important issues, such as the interaction of radiotherapy and systemic therapy and the avoidance of treatment complications. With the development of modern technology, highly conformal radiotherapy techniques have become more complicated, yet also more widely employed. This book will equip readers with the knowledge required to set up practices to deliver quality brain and spinal radiation therapy appropriate to each patient. It will be of benefit to radiation oncologists, clinical oncologists, medical physicists, medical dosimetrists, radiation therapists, and senior nurses as well as medical oncologists and surgical oncologists with an interest in radiotherapy.
Modern medical imaging and radiation therapy technologies are so complex and computer driven that it is difficult for physicians and technologists to know exactly what is happening at the point-of-care. Medical physicists responsible for filling this gap in knowledge must stay abreast of the latest advances at the intersection of medical imaging an
Radiation oncology is integrated with medical physics for a unique look at the state of the art in cancer patient care. World-renowned authors provide a complete discussion of treatment planning featuring the clinical, physical, and technical aspects involved. Coverage includes 3-D conformal treatment and other advancements in computer technology and medical imaging to bring the reader a modern perspective on treatment planning.
This book concisely reviews important advances in radiation oncology, providing practicing radiation oncologists with a fundamental understanding of each topic and an appreciation of its significance for the future of radiation oncology. It explores in detail the impact of newer imaging modalities, such as multiparametric magnetic resonance imaging (MRI) and positron emission tomography (PET) using fluorodeoxyglucose (FDG) and other novel agents, which deliver improved visualization of the physiologic and phenotypic features of a given cancer, helping oncologists to provide more targeted radiotherapy and assess the response. Due consideration is also given to how advanced technologies for radiation therapy delivery have created new treatment options for patients with localized and metastatic disease, highlighting the increasingly important role of image-guided radiotherapy in treating systemic and oligometastatic disease. Further topics include the potential value of radiotherapy in enhancing immunotherapy thanks to the broader immune-stimulatory effects, how cancer stem cells and the tumor microenvironment influence response, and the application of mathematical and systems biology methods to radiotherapy.