Computational Modeling of Microwave Tumor Ablation

Radmilović-Radjenović, M.; Bošković, Nikola; Radjenović, Branislav

doi:10.3390/bioengineering9110656

Cited by 5 publications

(3 citation statements)

References 115 publications

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“…However, it is assumed that both the tissue and blood are at the same temperature ( T t = T b = T ), according to the local thermal equilibrium (LTE) concept. The perfusion term in Pennes BHTE is therefore split into a modified perfusion term and a convective term in the LTE and LTNE models, respectively (Radmilović‐Radjenović et al, 2022; Tucci et al, 2021). Examples of expected results for thermal field induced by LIPUS and FUS are demonstrated in Figure 5d,e.…”

Section: Computational Models For Tus Applicationsmentioning

confidence: 99%

Ultrasound‐mediated nano‐sized drug delivery systems for cancer treatment: Multi‐scale and multi‐physics computational modeling

Kashkooli

Hornsby

Kolios

et al. 2023

WIREs Nanomed Nanobiotechnol

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Computational modeling enables researchers to study and understand various complex biological phenomena in anticancer drug delivery systems (DDSs), especially nano‐sized DDSs (NSDDSs). The combination of NSDDSs and therapeutic ultrasound (TUS), that is, focused ultrasound and low‐intensity pulsed ultrasound, has made significant progress in recent years, opening many opportunities for cancer treatment. Multiple parameters require tuning and optimization to develop effective DDSs, such as NSDDSs, in which mathematical modeling can prove advantageous. In silico computational modeling of ultrasound‐responsive DDS typically involves a complex framework of acoustic interactions, heat transfer, drug release from nanoparticles, fluid flow, mass transport, and pharmacodynamic governing equations. Owing to the rapid development of computational tools, modeling the different phenomena in multi‐scale complex problems involved in drug delivery to tumors has become possible. In the present study, we present an in‐depth review of recent advances in the mathematical modeling of TUS‐mediated DDSs for cancer treatment. A detailed discussion is also provided on applying these computational models to improve the clinical translation for applications in cancer treatment.This article is categorized under: Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease

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Section: Computational Models For Tus Applicationsmentioning

confidence: 99%

Ultrasound‐mediated nano‐sized drug delivery systems for cancer treatment: Multi‐scale and multi‐physics computational modeling

Kashkooli

Hornsby

Kolios

et al. 2023

WIREs Nanomed Nanobiotechnol

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“…Treatment planning [35] , [36] , [37] and computational models are important tools currently under development for many modalities to guide and tailor interstitial thermal ablation procedures and may provide for safer and more effective outcomes [38] , [39] , [40] . These planning and modeling tools can determine optimal designs and patterns of use, and through patient specific treatment planning optimize the device operating parameters and placement to selectively improve the tumor or target ablative temperature and thermal dose coverage.…”

Section: Introductionmentioning

confidence: 99%

Treatment Planning Strategies for Interstitial Ultrasound Ablation of Prostate Cancer

Gupta,

Heffter,

Zubair

et al. 2024

IEEE Open J. Eng. Med. Biol.

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To develop patient-specific 3D models using Finite-Difference Time-Domain (FDTD) simulations and pre-treatment planning tools for the selective thermal ablation of prostate cancer with interstitial ultrasound. This involves the integration with a FDA 510(k) cleared catheter-based ultrasound interstitial applicators and delivery system. Methods: A 3D generalized "prostate" model was developed to generate temperature and thermal dose profiles for different applicator operating parameters and anticipated perfusion ranges. A priori planning, based upon these pre-calculated lethal thermal dose and iso-temperature clouds, was devised for iterative device selection and positioning. Full 3D patient-specific anatomic modeling of actual placement of single or multiple applicators to conformally ablate target regions can be applied, with optional integrated pilot-point temperature-based feedback control and urethral/rectum cooling. These numerical models were verified against previously reported ex-vivo experimental results obtained in soft tissues. Results: For generic prostate tissue, 360 treatment schemes were simulated based on the number of transducers (1-4), applied power (8-20 W/cm 2 ), heating time (5, 7.5, 10 min), and blood perfusion (0, 2.5, 5 kg/m 3 /s) using forward treatment modelling. Selectable ablation zones ranged from 0.8-3.0 cm and 0.8-5.3 cm in radial and axial directions, respectively. 3D patientspecific thermal treatment modeling for 12 Cases of T2/T3 prostate disease demonstrate applicability of workflow and technique for focal, quadrant and hemi-gland ablation. A temperature threshold (e.g., Tthres = 52 °C) at the treatment margin, emulating placement of invasive temperature sensing, can be applied for pilot-point feedback control to improve conformality of thermal ablation. Also, binary power control (e.g., Treg = 45 °C) can be applied which will regulate the applied power level to maintain the surrounding temperature to a safe limit or maximum threshold until the set heating time. Conclusions: Prostate-specific simulations of interstitial ultrasound applicators were used to generate a library of thermal-dose distributions to visually optimize and set applicator positioning and directivity during a priori treatment planning pre-procedure. Anatomic 3D forward treatment planning in patient-specific models, along with optional temperature-based feedback control, demonstrated single and multi-applicator

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“…Modeling MWA as a multiphysics problem involves modeling multiple physical phenomena that occur during the procedure, including electromagnetic wave propagation, heat transfer, and tissue damage [14,15]. These phenomena are interrelated, and modeling them together can provide a more accurate and comprehensive understanding of tissue behavior during the procedure [16,17].…”

Section: Introductionmentioning

confidence: 99%

Finite Element Analysis of Microwave Tumor Ablation Based on Open-Source Software Components

Bošković

Radmilović-Radjenović

Radjenović

2023

Mathematics

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Microwave ablation is a procedure for treating various types of cancers during which a small needle-like probe is inserted inside the tumor, which delivers microwave energy, causes tissue heating, and effectively produces necrosis of the tumor tissue. Mathematical models of microwave ablation involve the modeling of multiple physical phenomena that occur during the procedure, including electromagnetic wave propagation, heat transfer, and tissue damage. In this study, a complete model of a microwave ablation procedure based on open-source software components is presented. First, the comprehensive procedure of mesh creation for the complete geometric arrangement of the microwave ablation, including a multi-slot coaxial antenna, a real liver tumor taken from the database, and the surrounding liver tissue, is described. It is demonstrated that utilizing smart meshing procedures significantly reduces the usage of computational resources and simulation time. An accurate custom explicit Euler time loop was designed to obtain temperature values and estimate tissue necrosis across the computational domain during the time of microwave ablation. The simulation results obtained by solving the electromagnetic field using the finite element method in the frequency domain are presented and analyzed. The simulation was performed for a microwave frequency of 2.45 GHz, and the volumetric distribution of temperature and estimation of cell damage over 600 s are presented.

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Computational Modeling of Microwave Tumor Ablation

Cited by 5 publications

References 115 publications

Ultrasound‐mediated nano‐sized drug delivery systems for cancer treatment: Multi‐scale and multi‐physics computational modeling

Ultrasound‐mediated nano‐sized drug delivery systems for cancer treatment: Multi‐scale and multi‐physics computational modeling

Treatment Planning Strategies for Interstitial Ultrasound Ablation of Prostate Cancer

Finite Element Analysis of Microwave Tumor Ablation Based on Open-Source Software Components

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