Authored and edited by internationally recognized authorities and subject area spec
Trade Review
“Although many radiation protection scientists and engineers use dose coefficients, few know the origin of those dose coefficients. This is the first book in over 40 years to address the topic of radiation protection dosimetry in intimate detail.
This is a significant volume providing an overview of the field of radiation protection dosimetry, elaborating on the foundational concepts, historical evolution of regulation and guidance, scientific models, and measurements of exposure and uptake, and addressing application of these models in evaluating radiation exposure/uptake risk. It is part of the International Organization for Medical Physics book series in medical physics and biomedical engineering. The book provides a comprehensive summary of the current state-of-the art computational dosimetry techniques for radiation protection, with a clear, overarching goal of capturing the high-level knowledge used to generate fundamental radiation protection dosimetry quantities. The book addresses these concepts and regulatory applications considering both external and internal pathways. The methods presented are largely based on computational approaches and results from the latest International Commission on Radiological Protection (ICRP) and the International Commission on Radiation Units (ICRU). As such, the book is appropriate for both a national and international audience including medical physicists, health physicists, radiation protection specialists, nuclear medicine practitioners, epidemiologists, and regulators. Other groups that would benefit from the information include students, academic physicists/dosimetrists, and laboratory researchers.
The book contains the most up-to-date computational dosimetry models with each topic covered by internationally recognized experts in that field of study. After reviewing fundamental concepts and an engaging historical review of radiation protection guidance in the United States (with parallel coverage of the international recommendations), the book takes deep dives into several key topics: radiation detection and measurement, reference individuals (and associated phantoms) defined for external and internal radiation dosimetry, as well as biokinetic and dosimetric models. Additional key chapters include a comprehensive treatment of dose coefficients (and computational dosimetry approaches), cancer risk coefficients (considering both philosophy and application), and the interpretation of bioassay results to assess the intake of radionuclides.
This book elucidates important topics in a much more practical manner than highly technical publications. In addition, having the detailed information in a single, combined, high-quality volume with primary references provided is a plus. The included sample calculations and detailed case studies are exceptionally useful inclusions. This is an important book that ensures key knowledge transfer from outgoing subject matter experts in radiation protection to incoming generations.”
—Lawrence Dauer, Ph.D. (Memorial Sloan-Kettering Cancer Center) in Doody’s Core Titles Review 2022.
Table of Contents
Chapter 1: Introduction. Chapter 2: Fundamental Concepts and Quantities. Chapter 3: Evolution of Radiation Protection Guidance in the United States. Chapter 4: Radiation Detection and Measurement. Chapter 5: Reference Individuals Defined for External and Internal Radiation Dosimetry. Chapter 6: Biokinetic Models. Chapter 7: Dosimetric Models. Chapter 8: Dose Coefficients. Chapter 9: Cancer Risk Coefficients. Chapter 10: Interpretation of Bioassay Results to Assess the Intake of Radionuclides.
