This book, now in an extensively revised and updated second edition, provides a comprehensive overview of both machine learning and deep learning and their role in oncology, medical physics, and radiology. Readers will find thorough coverage of basic theory, methods, and demonstrative applications in these fields. An introductory section explains machine and deep learning, reviews learning methods, discusses performance evaluation, and examines software tools and data protection. Detailed individual sections are then devoted to the use of machine and deep learning for medical image analysis, treatment planning and delivery, and outcomes modeling and decision support. Resources for varying applications are provided in each chapter, and software code is embedded as appropriate for illustrative purposes. The book will be invaluable for students and residents in medical physics, radiology, and oncology and will also appeal to more experienced practitioners and researchers and members ofapplied machine learning communities.
Innehållsförteckning
Part I. Introduction.- 1. What are Machine and Deep Learning?.- 2. Computational Learning Basics.- 3. Overview of Conventional Machine Learning Methods.- 4. Overview of Deep Machine Learning Methods.- 5. Quantum Computing for Machine Learning.- 6. Performance Evaluation.- 7. Software Tools for Machine and Deep learning.- 8. Data sharing, protection and bioethics.- Part II. Machine Learning for Medical Image Analysis.- 9. Detection of Cancer Lesions from Imaging.- 10. Diagnosis of Malignant and Benign Tumours.- 11. Auto-contouring for image-guidance and treatment planning.- Part III. Machine Learning for Treatment planning & Delivery.- 12. Quality Assurance and error prediction.- 13. Knowledge-based treatment planning.- 14. Intelligent respiratory motion management.- Part IV. Machine Learning for Outcomes Modeling and Decision Support.- 15. Prediction of oncology treatment outcomes.- 16. Radiomics and radiogenomics.- 17. Modelling of Radiotherapy Response (TCP/NTCP).- 18. Smartadaptive treatment strategies.- 19. Machine learning in clinical trials.
Om författaren
Issam El Naqa is founding Chair of Machine Learning Department and Associate Member of Radiation Oncology at Moffitt Cancer Center in Tampa, Florida.. He is board certified as a medical physicist by the American Board of Radiology. Dr. El Naqa received his BSc (1992) and MSc (1995) in Electrical and Communication Engineering from the University of Jordan, Jordan. He completed his Ph D (2002) in Electrical and Computer Engineering at the Illinois Institute of Technology, Chicago, IL, USA, receiving the highest academic distinction award for his work. He also completed an MA (2007) in Biology Science at Washington University, where he was hired as an instructor (2005–7) and then an Assistant Professor (2007–10) in the departments of radiation oncology and the division of biomedical and biological sciences. He subsequently became an Associate Professor at Mc Gill University Health Centre/Medical Physics Unit (2010-15). He later joined the Department of Radiation oncology atthe University of Michigan at Ann Arbor (2015-20), where he was a Professor and associate member in Applied Physics and the Michigan institute of data science. Dr. El Naqa is a recognized authority in the fields of machine learning, data analytics, and oncology outcomes modeling and has published extensively in these areas with more than 200+ peer-reviewed journal publications and 4 edited textbooks. He has been a member and fellow of several academic and professional societies including AAPM and IEEE. His research has been funded by several federal and private grants in Canada and the USA and served on national and international study sections. He acts as a peer-reviewer and editorial board member for several leading international journals in his areas of expertise.
Martin J Murphy is Professor Emeritus of radiation oncology at Virginia Commonwealth University (VCU), where he directed research into image-guided surgery and radiation therapy, employing principles of machine learning and neural networks. He received his Ph D in physics from the University of Chicago. Subsequently, he did research in nuclear physics, astrophysics, and space sciences at the Lawrence Berkeley Laboratory, the University of Washington, and the Lockheed Palo Alto Research Laboratory before joining the original development team for the Cyber Knife in 1992. He continued Cyber Knife development and other image-guidance applications at Stanford before joining the radiation oncology department at VCU in 2003. He has been the principal investigator for numerous NIH and private sector grants to apply robotics and machine learning to image guidance.