Title :
Computational electromagnetic modeling is key in objective control of hyperthermia
Author :
van Rhoon, Gc ; Paulides, Mm ; Drizdal, T.
Author_Institution :
Dept. Radiat. Oncology, Erasmus MC Cancer Inst., Rotterdam, Netherlands
Abstract :
Confining treatment to the tumor to improve therapeutic outcome and reduce toxicity, is a hot issue in cancer research. Hyperthermia is recognized as a strong sensitizer for radiotherapy and chemotherapy enhancing tumor control without increasing toxicity. Today´s electromagnetic hyperthermia systems heat large tissue volumes with limited ability to selectively heat the tumor. Fortunately, tremendous improvements in 3-dimensional electromagnetic & temperature modelling provide an exciting opportunity to design advanced multi-element electromagnetic applicator systems. Together with feedback control using MR non-invasive thermometry and smart E-field sensors, this paves the way for selective tumor heating and potentially prescription of a thermal dose.
Keywords :
biomedical MRI; biomedical equipment; cancer; dosimetry; hyperthermia; intelligent sensors; radiation therapy; temperature measurement; toxicology; tumours; 3-dimensional electromagnetic modelling; MR noninvasive thermometry; cancer research; chemotherapy; computational electromagnetic modeling; confining treatment; feedback control; multielement electromagnetic applicator systems; objective hyperthermia control; radiotherapy; selective tumor heating; smart E-field sensors; temperature modelling; therapeutic outcome; thermal dose; tissue volumes; toxicity; tumor control; Applicators; Electromagnetics; Hyperthermia; Neck; Planning; Temperature measurement; Tumors; electromagnetic modeling; hyperthermia; online control;
Conference_Titel :
Antennas and Propagation (EuCAP), 2015 9th European Conference on
Conference_Location :
Lisbon
