论文信息 - A semi-empirical treatment planning model for optimization of multiprobe cryosurgery

A semi-empirical treatment planning model for optimization of multiprobe cryosurgery

A model is presented for treatment planning of multiprobe cryosurgery. In this model a thermal simulation algorithm is used to generate temperature distribution from cryoprobes, visualize isotherms in the anatomical region of interest, and provide tools to assist estimation of the amount of freezing damage to the target and surrounding normal structures. Calculations may be performed for any given freezing time for the selected set of operation parameters. The thermal simulation is based on solving the transient heat conduction equation using finite element methods for a multiprobe geometry. As an example, a semi-empirical optimization of 2D placement of 6 cryoprobes and their thermal protocol for the first freeze cycle is presented. The effectiveness of the optimized treatment protocol was estimated by generating temperature-volume histograms and calculating the objective function for the anatomy of interest.

[1] J Y Gillenwater,et al. Determination of optimal freezing parameters of human prostate cancer in a nude mouse model , 1999, The Prostate.

[2] M S Roos,et al. Monitoring cryosurgery in the brain and in the prostate with proton NMR. , 1993, Cryobiology.

[3] Boris Rubinsky,et al. Optimization of Multiprobe Cryosurgery , 1992 .

[4] G. Sandison,et al. X-ray CT monitoring of iceball growth and thermal distribution during cryosurgery. , 1998, Physics in medicine and biology.

[5] Y Rabin,et al. Numerical solution of the multidimensional freezing problem during cryosurgery. , 1998, Journal of biomechanical engineering.

[6] Anastas Lazaridis,et al. A numerical solution of the multidimensional solidification (or melting) problem , 1970 .

[7] R Mohan,et al. Dose-volume histograms. , 1991, International journal of radiation oncology, biology, physics.

[8] R W Günther,et al. Imaging of interstitial cryotherapy--an in vitro comparison of ultrasound, computed tomography, and magnetic resonance imaging. , 1999, Cryobiology.

[9] A. Gage,et al. Mechanisms of tissue injury in cryosurgery. , 1998, Cryobiology.

[10] B. Rubinsky,et al. Analytic Solutions to the Heat Equation Involving a Moving Boundary with Applications to the Change of Phase Problem (the Inverse Stefan Problem) , 1978 .

[11] C Raphael,et al. Mathematical modelling of objectives in radiation therapy treatment planning. , 1992, Physics in medicine and biology.