by Janine Matschek, Eric Bullinger, Friedrich von Haeseler, Martin Skalej, Rolf Findeisen
Abstract:
Radiofrequency ablation is a valuable tool in the treatment of many diseases, especially cancer. However, controlled heating up to apoptosis of the desired target tissue in complex situations, e.g. in the spine, is challenging and requires experienced interventionalists. For such challenging situations a mathematical model of radiofrequency ablation allows to understand, improve and optimise the outcome of the medical therapy. The main contribution of this work is the derivation of a tailored, yet expandable mathematical model, for the simulation, analysis, planning and control of radiofrequency ablation in complex situations. The dynamic model consists of partial differential equations that describe the potential and temperature distribution during intervention. To account for multipolar operation, time-dependent boundary conditions are introduced. Spatially distributed parameters, like tissue conductivity and blood perfusion, allow to describe the complex 3D environment representing diverse involved tissue types in the spine. To identify the key parameters affecting the prediction quality of the model, the influence of the parameters on the temperature distribution is investigated via a sensitivity analysis. Simulations underpin the quality of the derived model and the analysis approach. The proposed modelling and analysis schemes set the basis for intervention planning, state- and parameter estimation, and control.
Reference:
Mathematical 3D modelling and sensitivity analysis of multipolar radiofrequency ablation in the spine (Janine Matschek, Eric Bullinger, Friedrich von Haeseler, Martin Skalej, Rolf Findeisen), In Mathematical Biosciences, volume 284, 2017.
Bibtex Entry:
@article{matschek_mathematical_2017,
title = {Mathematical 3D modelling and sensitivity analysis of multipolar radiofrequency ablation in the spine},
volume = {284},
issn = {0025-5564},
url = {http://www.sciencedirect.com/science/article/pii/S0025556416300694},
doi = {https://doi.org/10.1016/j.mbs.2016.06.008},
abstract = {Radiofrequency ablation is a valuable tool in the treatment of many diseases, especially cancer. However, controlled heating up to apoptosis of the desired target tissue in complex situations, e.g. in the spine, is challenging and requires experienced interventionalists. For such challenging situations a mathematical model of radiofrequency ablation allows to understand, improve and optimise the outcome of the medical therapy. The main contribution of this work is the derivation of a tailored, yet expandable mathematical model, for the simulation, analysis, planning and control of radiofrequency ablation in complex situations. The dynamic model consists of partial differential equations that describe the potential and temperature distribution during intervention. To account for multipolar operation, time-dependent boundary conditions are introduced. Spatially distributed parameters, like tissue conductivity and blood perfusion, allow to describe the complex 3D environment representing diverse involved tissue types in the spine. To identify the key parameters affecting the prediction quality of the model, the influence of the parameters on the temperature distribution is investigated via a sensitivity analysis. Simulations underpin the quality of the derived model and the analysis approach. The proposed modelling and analysis schemes set the basis for intervention planning, state- and parameter estimation, and control.},
journal = {Mathematical Biosciences},
author = {Matschek, Janine and Bullinger, Eric and Haeseler, Friedrich von and Skalej, Martin and Findeisen, Rolf},
year = {2017},
keywords = {Mathematical modelling, Multipolar radiofrequency ablation, Sensitivity analysis, Spinal column},
pages = {51 -- 60}
}