Shares the viewpoint of a person standing with one foot in physics and the other in radiation oncology
Designed to assist practitioners in physics understand the problems of, and find solutions for, practitioners in radiation oncology and vice versa
Written by an international expert in proton, light ion, and heavy charged particle radiotherapy
Michael Goitein, Ph.D., is Professor of Radiation Therapy Emeritus (Radiation Biophysics) Harvard Medical School. He is certified in Therapeutic Radiological Physics by the American Board of Radiology and in Medical Physics by the Swiss Society of Medical Physics and Biology. He is also a Fellow in the American Association of Physicists in Medicine and an Honorary Member of the Belgian Society of Radiotherapy and Oncology.
The papers collected in this hugely useful volume cover the principle physical and biological aspects of radiation therapy and in addition, address practical clinical considerations in the planning and delivering of that therapy. The importance of the assessment of uncertainties is emphasized. Topics include an overview of the physics of the interactions of radiation with matter and the definition of the goals and the design of radiation therapy approaches.
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Radiation Oncology: A Physicist's-Eye View was written for both physicists and medical oncologists with the aim of helping them approach the use of radiation in the treatment of cancer with understanding, confidence, and imagination. The book will let practitioners in one field understand the problems of, and find solutions for, practitioners in the other. It will help them to know "why" certain approaches are fruitful while, at the same time, encouraging them to ask the question "Why not?" in the face of assertions that some proposal of theirs is impractical, unreasonable, or impossible. Unlike a textbook, formal and complete developments of the topics are not among the goals. Instead, the reader will develop a foundation for understanding what the author has found to be matters of importance in radiation oncology during over thirty years of experience. Presentations cover, in largely non-technical language, the principal physical and biological aspects of radiation treatment and address practical clinical considerations in planning and delivering therapy. The importance of the assessment of uncertainties is emphasized. Topics include: an overview of the physics of the interactions of radiation with matter; the definition of the goals and the design of radiation therapy approaches; living with uncertainty; biophysical models of radiation damage; computer-based optimization of treatments; and proton therapy. Formulae and quantitation in general have been avoided in the belief that an understanding of the majority of important medical and biological issues in radiation oncology generally cannot be achieved through mathematical relationships. This unique and highly readable book will be indispensable both to beginners and to those with experience in either medical physics or radiation oncology.
The author, who is Professor of Radiation Oncology Emeritus at Harvard Medical School, was an early pioneer in the development of image-based treatment planning and has been responsible for developing and putting into clinical practice such widely used tools as: digitally reconstructed radiographs, dose-volume histograms, and beam´s-eye view and has been a leader in the development of proton beam therapy.
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The presentations cover the principle physical and biological aspects of radiation therapy and address practical clinical considerations in planning and delivering therapy. The importance of the assessment of uncertainties is emphasized. Topics include: an overview of the physics of the interactions of radiation with matter; the definition of the goals and the design of radiation therapy approaches; proton therapy; living with uncertainty; biophysical models of radiation damage; computer-based optimization of treatments; and the reporting of results.
Radiation in the Treatment of Cancer.- Uncertainty.- Mapping Anatomy.- Designing a Treatment Beam.- Biology Matters.- Designing a Treatment Plan.- Motion Management.- Planning Manually.- IMRT and "Optimization”.- Proton Therapy in Water.- Proton Therapy in the Patient.- Quality Assurance.- Confidence.
Radiation Oncology: A Physicist's-Eye View was written for both physicists and medical oncologists with the aim of helping them approach the use of radiation in the treatment of cancer with understanding, confidence, and imagination. The book will let practitioners in one field understand the problems of, and find solutions for, practitioners in the other. It will help them to know "why" certain approaches are fruitful while, at the same time, encouraging them to ask the question "Why not?" in the face of assertions that some proposal of theirs is impractical, unreasonable, or impossible. Unlike a textbook, formal and complete developments of the topics are not among the goals. Instead, the reader will develop a foundation for understanding what the author has found to be matters of importance in radiation oncology during over thirty years of experience. Presentations cover, in largely non-technical language, the principal physical and biological aspects of radiation treatment and address practical clinical considerations in planning and delivering therapy. The importance of the assessment of uncertainties is emphasized. Topics include: an overview of the physics of the interactions of radiation with matter; the definition of the goals and the design of radiation therapy approaches; living with uncertainty; biophysical models of radiation damage; computer-based optimization of treatments; and proton therapy. Formulae and quantitation in general have been avoided in the belief that an understanding of the majority of important medical and biological issues in radiation oncology generally cannot be achieved through mathematical relationships. This unique and highly readable book will be indispensable both to beginners and to those with experience in either medical physics or radiation oncology.
The author, who is Professor of Radiation Oncology Emeritus at Harvard Medical School, was an early pioneer in the development of image-based treatment planning and has been responsible for developing and putting into clinical practice such widely used tools as: digitally reconstructed radiographs, dose-volume histograms, and beam´s-eye view and has been a leader in the development of proton beam therapy.
From the reviews:
"It provides a lucid account of some of the modern technologies and methods in radiation therapy in which the author has been a leader. ... Goitein´s avoidance of mathematical formulas makes his treatise easily readable. The footnotes that elaborate concepts and definitions are useful, and the author explains concepts clearly and provides extensive illustrations and understandable diagrams. ... is an invaluable resource not only for the experienced practitioner but also for the radiation oncologist, medical physicist, or dosimetrist who is new to the field." (Dan Jones, Physics Today, Vol. 61 (12), December, 2008)
Radiation Oncology: A Physicist's-Eye View was written for both physicists and medical oncologists with the aim of helping them approach the use of radiation in the treatment of cancer with understanding, confidence, and imagination. The book will let practitioners in one field understand the problems of, and find solutions for, practitioners in the other. It will help them to know "why" certain approaches are fruitful while, at the same time, encouraging them to ask the question "Why not?" in the face of assertions that some proposal of theirs is impractical, unreasonable, or impossible. Unlike a textbook, formal and complete developments of the topics are not among the goals. Instead, the reader will develop a foundation for understanding what the author has found to be matters of importance in radiation oncology during over thirty years of experience. Presentations cover, in largely non-technical language, the principal physical and biological aspects of radiation treatment and address practical clinical considerations in planning and delivering therapy. The importance of the assessment of uncertainties is emphasized. Topics include: an overview of the physics of the interactions of radiation with matter; the definition of the goals and the design of radiation therapy approaches; living with uncertainty; biophysical models of radiation damage; computer-based optimization of treatments; and proton therapy. Formulae and quantitation in general have been avoided in the belief that an understanding of the majority of important medical and biological issues in radiation oncology generally cannot be achieved through mathematical relationships. This unique and highly readable book will be indispensable both to beginners and to those with experience in either medical physics or radiation oncology.
The author, who is Professor of Radiation Oncology Emeritus at Harvard Medical School, was an early pioneer in the development of image-based treatment planning and has been responsible for developing and putting into clinical practice such widely used tools as: digitally reconstructed radiographs, dose-volume histograms, and beam's-eye view and has been a leader in the development of proton beam therapy.
Radiation in the Treatment of Cancer.- Uncertainty.- Mapping Anatomy.- Designing a Treatment Beam.- Biology Matters.- Designing a Treatment Plan.- Motion Management.- Planning Manually.- IMRT and "Optimization".- Proton Therapy in Water.- Proton Therapy in the Patient.- Quality Assurance.- Confidence.
From the reviews:
"It provides a lucid account of some of the modern technologies and methods in radiation therapy in which the author has been a leader. ... Goitein's avoidance of mathematical formulas makes his treatise easily readable. The footnotes that elaborate concepts and definitions are useful, and the author explains concepts clearly and provides extensive illustrations and understandable diagrams. ... is an invaluable resource not only for the experienced practitioner but also for the radiation oncologist, medical physicist, or dosimetrist who is new to the field." (Dan Jones, Physics Today, Vol. 61 (12), December, 2008)
Michael Goitein, Ph.D., is Professor of Radiation Therapy Emeritus (Radiation Biophysics) Harvard Medical School. He is certified in Therapeutic Radiological Physics by the American Board of Radiology and in Medical Physics by the Swiss Society of Medical Physics and Biology. He is also a Fellow in the American Association of Physicists in Medicine and an Honorary Member of the Belgian Society of Radiotherapy and Oncology.
Über den Autor
Michael Goitein, Ph.D., is Professor of Radiation Therapy Emeritus (Radiation Biophysics) Harvard Medical School. He is certified in Therapeutic Radiological Physics by the American Board of Radiology and in Medical Physics by the Swiss Society of Medical Physics and Biology. He is also a Fellow in the American Association of Physicists in Medicine and an Honorary Member of the Belgian Society of Radiotherapy and Oncology.
Inhaltsverzeichnis
Radiation in the Treatment of Cancer.- Uncertainty.- Mapping Anatomy.- Designing a Treatment Beam.- Biology Matters.- Designing a Treatment Plan.- Motion Management.- Planning Manually.- IMRT and ¿Optimization¿.- Proton Therapy in Water.- Proton Therapy in the Patient.- Quality Assurance.- Confidence.
Klappentext
Radiation Oncology: A Physicist's-Eye View was written for both physicists and medical oncologists with the aim of helping them approach the use of radiation in the treatment of cancer with understanding, confidence, and imagination. The book will let practitioners in one field understand the problems of, and find solutions for, practitioners in the other. It will help them to know "why" certain approaches are fruitful while, at the same time, encouraging them to ask the question "Why not?" in the face of assertions that some proposal of theirs is impractical, unreasonable, or impossible. Unlike a textbook, formal and complete developments of the topics are not among the goals. Instead, the reader will develop a foundation for understanding what the author has found to be matters of importance in radiation oncology during over thirty years of experience. Presentations cover, in largely non-technical language, the principal physical and biological aspects of radiation treatment and address practical clinical considerations in planning and delivering therapy. The importance of the assessment of uncertainties is emphasized. Topics include: an overview of the physics of the interactions of radiation with matter; the definition of the goals and the design of radiation therapy approaches; living with uncertainty; biophysical models of radiation damage; computer-based optimization of treatments; and proton therapy. Formulae and quantitation in general have been avoided in the belief that an understanding of the majority of important medical and biological issues in radiation oncology generally cannot be achieved through mathematical relationships. This unique and highly readable book will be indispensable both to beginners and to those with experience in either medical physics or radiation oncology.
The author, who is Professor of Radiation Oncology Emeritus at Harvard Medical School, was an early pioneer in the development of image-based treatment planning and has been responsible for developing and putting into clinical practice such widely used tools as: digitally reconstructed radiographs, dose-volume histograms, and beam¿s-eye view and has been a leader in the development of proton beam therapy.
The presentations cover the principle physical and biological aspects of radiation therapy and address practical clinical considerations in planning and delivering therapy. The importance of the assessment of uncertainties is emphasized. Topics include: an overview of the physics of the interactions of radiation with matter; the definition of the goals and the design of radiation therapy approaches; proton therapy; living with uncertainty; biophysical models of radiation damage; computer-based optimization of treatments; and the reporting of results.
