AI Article Synopsis
- RF ablation is an effective method to decrease the size of thyroid nodules, and a finite element model was developed to optimize the procedure parameters like power and duration for better volume reduction rates.
- The model simulates the RF ablation process by addressing the electrical and thermal effects on tissue, utilizing equations to predict temperature distribution and tissue damage.
- Findings suggest that longer electrode tips are more efficient, needing less power and time for desired outcomes, while higher blood flow in tumors necessitates adjustments in RF settings to achieve the same volume reduction.
Article Abstract
Radiofrequency (RF) ablation represents an efficient strategy to reduce the volume of thyroid nodules. In this study, a finite element model was developed with the aim of optimizing RF parameters, e.g., input power and treatment duration, in order to achieve the target volume reduction rate (VRR) for a thyroid nodule. RF ablation is modelled as a coupled electro-thermal problem wherein the electric field is applied to induce tissue heating. The electric problem is solved with the Laplace equation, the temperature distribution is estimated with the Pennes bioheat equation, and the thermal damage is evaluated using the Arrhenius equation. The optimization model is applied to RF electrode with different active tip lengths in the interval from 5 mm to 40 mm at the 5 mm step. For each case, we also explored the influence of tumour blood perfusion rate on RF ablation outcomes. The model highlights that longer active tips are more efficient as they require lesser power and shorter treatment time to reach the target VRR. Moreover, this condition is characterized by a reduced transversal ablation zone. In addition, a higher blood perfusion increases the heat dispersion, requiring a different combination of RF power and time treatment to achieve the target VRR. The model may contribute to an improvement in patient-specific RF ablation treatment.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10604455 | PMC |
| http://dx.doi.org/10.3390/bioengineering10101210 | DOI Listing |
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