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- Author: Xenia-Rosemarie Reit
- Publisher: AV Akademikerverlag
- Year: 2012
- Pages: 76
- ISBN-10: 3639389441
- ISBN-13: 9783639389449
- Format: 15.2 x 22.9 x 0.5 cm, minkšti viršeliai
- Language: English
- SAVE -10% with code: EXTRA
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Description
A high intensity focused ultrasound (HIFU) treatment has a very complex therapy planning structure. In this thesis we introduce a workflow on the basis of a decomposition of the therapy plan into controllable but coupled subproblems. Under certain assumptions, including the decoupling of these subproblems, we first concentrate on the maximisation of the sonication area on a patient surface. The sound waves form a double cone in the center of which the main energy transfer to the tumour tissue takes place. A maximally opened cone allows for the use of as many degrees of freedom as possible which represents a good basis for further computations. The cone is restricted by so called areas of risk, which are healthy tissue domains. These areas should not be affected by the ultrasound. For a future simulation it is necessary to know about the temperature distribution in the focal points depending on the available parameters. We establish a short-cut model to overcome the time-consuming problem of solving the nonlinear wave equation at each data point. This short-cut model characterises the diffusion of heat using the heat equation. We solve the heat equation by using Green's functions.
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- Author: Xenia-Rosemarie Reit
- Publisher: AV Akademikerverlag
- Year: 2012
- Pages: 76
- ISBN-10: 3639389441
- ISBN-13: 9783639389449
- Format: 15.2 x 22.9 x 0.5 cm, minkšti viršeliai
- Language: English English
A high intensity focused ultrasound (HIFU) treatment has a very complex therapy planning structure. In this thesis we introduce a workflow on the basis of a decomposition of the therapy plan into controllable but coupled subproblems. Under certain assumptions, including the decoupling of these subproblems, we first concentrate on the maximisation of the sonication area on a patient surface. The sound waves form a double cone in the center of which the main energy transfer to the tumour tissue takes place. A maximally opened cone allows for the use of as many degrees of freedom as possible which represents a good basis for further computations. The cone is restricted by so called areas of risk, which are healthy tissue domains. These areas should not be affected by the ultrasound. For a future simulation it is necessary to know about the temperature distribution in the focal points depending on the available parameters. We establish a short-cut model to overcome the time-consuming problem of solving the nonlinear wave equation at each data point. This short-cut model characterises the diffusion of heat using the heat equation. We solve the heat equation by using Green's functions.
Reviews