Tiziana Rancati, Claudio Fiorino
March 25, 2019 Forthcoming
Reference - 472 Pages - 62 B/W Illustrations
ISBN 9781138198098 - CAT# K31338
Series: Series in Medical Physics and Biomedical Engineering
For Instructors Request Inspection Copy
The treatment of a patient with radiation therapy is planned to find the optimal way to treat a tumour while minimizing the dose received by the surrounding normal tissues. In order to better exploit the possibilities of this process, the availability of accurate and quantitative knowledge of the peculiar responses of the different tissues is of paramount importance.
This book provides an invaluable tutorial for radiation oncologists, medical physicists, and dosimetrists involved in the planning optimization phase of treatment. It presents a practical, accessible, and comprehensive summary of the field’s current research and knowledge regarding the response of normal tissues to radiation. This is the first comprehensive attempt to do so since the publication of the QUANTEC guidelines in 2010.
PART I: DATA AND MODELS.
The importance of the quality of data
Building a predictive model of toxicity: methods.
Potentials and limits of phenomenological models.
PART II: PREDICTING THE RISK OF TOXICITY IN PRACTICE.
Pelvis: rectal and bowel toxicity.
Pelvis: urinary toxicity and sexual dysfunctions.
Optical structures and ears.
Head and neck: parotids.
Head and neck: structures involved in swallowing and nutritional problems.
Head and neck: larynx and structures involved in dysphonia.
Thorax: lungs and esophagous.
Heart and vascular problems.
Skin and fibrosis.
Bones and hematological toxicity.
Predicting toxicity in RT: a critical summary.
PART III VISION/CHALLENGES.
Data-sharing and toxicity modeling: a vision of the near future.
Quantitative imaging for assessing and predicting toxicity.
Including the 4th dimension into predictive models of toxicity.
Beyond DVH: 2D/3D based dose comparison to assess predictors of toxicity.
Predictive models and automatic planning: where are we going ?
Including genetic variables in NTCP models. Where are we? Where are we going?