Coupled electrical-thermal model for monopolar and bipolar radiofrequency liver tumor ablation

Soetaert, Frederik; Crevecoeur, Guillaume; Dupré, Luc

doi:10.1109/isfee.2016.7803150

Cited by 3 publications

(3 citation statements)

References 22 publications

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“…In addition, the survival and necrotic fractions of the tissue can be predicted respectively from the relations as follows [5,14]:…”

Section: Arrhenius Thermal Damage Model Of Tissuementioning

confidence: 99%

“…The commonly used probes for thermal therapies can be temperatureor power-controlled [2] and often aided with thermal sensors and various image-guided techniques [11]. The tissue temperature during ablation can reach significant values ranging from 50 • C to 110 • C [3], that combined with right application time may ultimately lead to coagulation and tissue necrosis [5,[12][13][14]. It should be noticed, that burning of tumors takes place with a certain margin of ablative tissue necrosis, difficult to unambiguously determine using available imaging methods during ablation procedures.…”

Section: Introductionmentioning

confidence: 99%

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Archives of Electrical Engineering

Gas,

Wyszkowska

2019

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Percutaneous RF ablation is one of alternative treatment for non-surgical liver tumors. Ablative changes in hepatic tissue can be successfully estimated using the finite element method. The authors created a 3D model of a multi-tine applicator immersed in liver tissue, and then determined the optimal values of voltage applied to such an RF electrode, which do not exceed the therapeutic temperature range valid during thermal ablation procedure. Importantly, the simulations were carried out for the RF electric probes with 2 to 5 evenly spaced arms. Additionally, the thermal damage of hepatic tissue for multi-armed applicators working at pre-defined limit values of voltages was established based on the Arrhenius model.

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“…In addition, the survival and necrotic fractions of the tissue can be predicted respectively from the relations as follows [5,14]:…”

Section: Arrhenius Thermal Damage Model Of Tissuementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Archives of Electrical Engineering

Gas,

Wyszkowska

2019

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“…IRE usually requires of extensive experimentation to optimize the process and maximize the desired cell destruction with minimum collateral damage. Besides, unlike purely thermal treatments like radiofrequency or microwave ablation [2], it requires in-vivo experiment to assess its biological effects [3]. This leads to a complex optimization process and makes the development of accurate models necessary.…”

Section: Introductionmentioning

confidence: 99%

Electro-thermal modeling of irreversible electroporation and validation method of electric field distribution

López-Alonso

Sarnago

Burdío

et al. 2020

JAE

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Nowadays, several applications of electroporation have been adopted in cancer therapy with promising results that have boosted research interest. To develop new treatment options, the development of electroporation models and measurement method in order to study the real distribution of the electric field potential are needed. Nowadays, current trends in electroporation techniques suggest the use of more powerful pulse generators that enables the treatment of larger tissue volumes. However, new challenges arise regarding the modeling of the electroporation process in large tissue volumes as well as the potential thermal effects when large amounts of energy are used. The aim of this paper is to propose a finite element analysis (FEA) based model using COMSOL of the irreversible electroporation process considering both electrical and thermal effects, and to validate it through in-vivo experimentation.Moreover, we propose a methodology for measuring the electrical potential in different points of a biological tissue during the application of a train of pulses to measure the distribution of the electric field inside the tissue. For this application, needle-based electrodes have been developed to achieve the least invasive measurement possible. These tools are aimed to improve the application of the electroporation treatment by reducing its side effects.

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Potential of Determining Thermal Dose for Ablation Therapies Using Ultrasound Elastography: An Ex Vivo Feasibility Study

Kling

Jiang

2018

2018 IEEE International Ultrasonics Symposium (IUS)

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Coupled electrical-thermal model for monopolar and bipolar radiofrequency liver tumor ablation

Cited by 3 publications

References 22 publications

Archives of Electrical Engineering

Archives of Electrical Engineering

Electro-thermal modeling of irreversible electroporation and validation method of electric field distribution

Potential of Determining Thermal Dose for Ablation Therapies Using Ultrasound Elastography: An Ex Vivo Feasibility Study

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