Title :
Analytical prediction and numerical confirmation of deep focused microwave hyperthermia in a human head
Author :
Rappaport, Carey M. ; Dunn, David
Author_Institution :
Northeastern Univ., Boston, MA, USA
Abstract :
By carefully selecting the electric field distribution around the entire surface of a human head, it is possible to generate a tightly-focused global power maximum at the deepest point within the brain. An analytic prediction of the optimum volume field distribution in a layered concentric head model is derived based on spherical harmonics, and a three-dimensional finite difference time domain (FDTD) computation using the corresponding source field for a discretized, MRI-based head model gives a very similar dissipated power distribution. This study demonstrates that microwave hyperthermia can be a feasible cancer treatment modality for tumors in the head, providing a well-resolved “hotspot” at depth without overheating any other healthy tissue
Keywords :
biomedical NMR; brain; finite difference time-domain analysis; focusing; hyperthermia; microwave heating; radiation therapy; 915 MHz; analytical prediction; cancer treatment modality; deep focused microwave hyperthermia; discretized MRI-based head model; dissipated power distribution; electric field distribution; healthy tissue; hotspot; human head; layered concentric head model; numerical confirmation; optimum volume field distribution; overheating; source field; spherical harmonics; three-dimensional finite difference time domain computation; tightly-focused global power maximum; tumors; Distributed computing; Finite difference methods; Harmonic analysis; Humans; Hyperthermia; Power distribution; Power generation; Power system harmonics; Predictive models; Time domain analysis;
Conference_Titel :
Bioengineering Conference, 1995., Proceedings of the 1995 IEEE 21st Annual Northeast
Conference_Location :
Bar Harbor, ME
Print_ISBN :
0-7803-2692-X
DOI :
10.1109/NEBC.1995.513756
