Image-based computational model for focused ultrasound ablation of liver tumor

Solovchuk, Maxim; Sheu, Tony W. H.; Thiriet, Marc

doi:10.1186/2194-3990-1-4

Cited by 10 publications

(6 citation statements)

References 22 publications

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“…Gas bubbles are formed in the focal area and this region can be seen as an echogenic region. Treatment planning [10][11][12][13] becomes therefore very important for US imaging. Before the treatment acoustic parameters of the transducer should be well adjusted in the case of US guided focused ultrasound therapy.…”

Section: Introductionmentioning

confidence: 99%

Temperature elevation by HIFU inex vivoporcine muscle: MRI measurement and simulation study

et al. 2014

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The present study demonstrated that for peak temperatures below 85-90 °C numerical simulation results are in excellent agreement with the experimental data in three dimensions. Both temperature rise and lesion size can be well predicted. Due to nonlinear effect the temperature in the focal region can be increased compared with the linear case. The current magnetic resonance imaging (MRI) resolution is not sufficient. Due to the inevitable averaging the measured temperature can be 10-30 °C lower than the peak temperature. Computational fluid dynamics can provide additional important information that is lost using a state of the art MRI device.

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Section: Introductionmentioning

confidence: 99%

Temperature elevation by HIFU inex vivoporcine muscle: MRI measurement and simulation study

et al. 2014

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“…To obtain the acoustic pressure, the nonlinear propagation equation (Westervelt) of the ultrasonic waves is used. The following full‐wave Westervelt equation, which is based on the effects of diffraction, absorption, and nonlinear propagation, is used 19–25 :

\begin{equation}{\nabla }^2p - \frac{1}{{{c}^2}}\frac{{{\partial }^2p}}{{\partial {t}^2}} + \frac{\delta }{{{c}^2}}\frac{\partial }{{\partial t}}({\nabla }^2p) = \frac{\beta }{{{\rho }_0{c}^4}}\frac{{{\partial }^2}}{{\partial {t}^2}}\left( {{p}^2} \right)\ \end{equation}

\begin{equation}\delta = \frac{1}{{{\rho }_0}}\left( {\frac{4}{3}\mu + {\mu }_B + \frac{{\left( {\gamma - 1} \right)k}}{{{c}_p}}} \right)\end{equation}

where p , c , ρ , and δ are the acoustic pressure, speed of the sound propagation in the medium, density, and the diffusivity of sound (Equation 2), respectively, and β

( {1 + \frac{B}{{2A}}} )

is a nonlinearity coefficient. In Equation (2), μ , μ B , γ , k , and c p are the dynamic viscosity coefficient, the bulk viscosity coefficient, the heat capacity ratio, the thermal conductivity, and the specific heat capacity, respectively.…”

Section: Methodsmentioning

confidence: 99%

Numerical study of high‐intensity focused ultrasound (HIFU) in fat reduction

MORTAZAVI

Mokhtari‐Dizaji

2023

Skin Research and Technology

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Introduction:This study aimed to investigate the effect of fat-layer thickness and focal depth on the pressure and temperature distribution of tissue. Methods:Computer simulations were performed for the skin-fat layer models during high-intensity focused ultrasound (HIFU) treatment. The acoustic pressure field was calculated using the nonlinear Westervelt equation and coupled with the Pennes bioheat transfer equation to obtain the temperature distribution. To investigate the effect of the thickness of the fat layer on pressure and thermal distributions, the thickness of the fat layer behind the focal point (z = 13.5 mm) changed from 8 to 24 mm by 2 mm step. The pressure and temperature distribution spectra were extracted. Results:The simulated results were validated using the experimental results with a 98% correlation coefficient (p < 0.05). There was a significant difference between the pressure amplitude and temperature distribution for the 8-14 mm thickness of the fat layer (p < 0.05). By changing the focal point from 11.5 to 13.5 mm, the maximum acoustic pressure at the focal point increased 66%, and the maximum temperature was 56%, respectively. Conclusion:Considering the specific treatment plan for each patient, according to the skin and fat layer thicknesses, can help prevent side effects and optimize the treatment process of HIFU.

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“…The third term represents attenuation due to thermal conductivity and fluid viscosity. The last term describes the acoustic nonlinearity, which explains the distortion of a wave due to the nonlinear effects and affects the thermal and mechanical changes inside the tissue medium [21].…”

Section: Propagation Of Acoustic Wave Into the Tissue Mediummentioning

confidence: 99%

Numerical analysis of thermal response of tissues subjected to high intensity focused ultrasound

Gupta

Srivastava

2018

International Journal of Hyperthermia

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The present work is concerned with the numerical investigation of the thermal response of tissuemimicking biological phantom(s) subjected to high intensity focused ultrasound (HIFU). Simulations have been performed on the 3-dimensional physical domain for two-layered as well as multi-layered medium consisting of water and liver tissue. Local pressure distribution within the body of the phantom has been calculated by solving the complete full-wave nonlinear form of Westervelt equation. The solution of the pressure wave equation has been coupled with Pennes bioheat transfer equation to determine the full field temperature distribution. Results in the form of pressure fields, temperature distributions and the corresponding thermal dosage in the targeted region of the tissue domain have been presented. Magnitudes of the maximum pressure (and hence the resultant temperature levels) in the focal region as obtained using the nonlinear form of Westervelt equation are found to be significantly higher than that determined based on the linear form of the equation. Compared to water, wherein the acoustic intensity is maximum, the addition of sub-layers of skin, fat, and muscle into water resulted in the reduction of the peak intensity and also shifted the intensity profiles along the direction of propagation of the acoustic waves. However, addition of liver tissue into water led to the shifting of intensity profile in the opposite direction i.e., towards the transducer. The results further reveal that due to the dependence of attenuation coefficient on the source frequency, the temperature at the focal region increases with an increase in the transducer frequency. The work is further extended from single lesion to multiple lesion generation through controlled movement of the transducer and the resultant transient full field temperature distribution has been presented. The concerned observations highlight the need of optimizing the thermal energy for each lesion, the inter spatial distance between different lesions and the delay time so as to ensure minimal thermal damage to the surrounding healthy cells as well as to reduce the total treatment duration.

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Image-based computational model for focused ultrasound ablation of liver tumor

Cited by 10 publications

References 22 publications

Temperature elevation by HIFU inex vivoporcine muscle: MRI measurement and simulation study

Temperature elevation by HIFU inex vivoporcine muscle: MRI measurement and simulation study

Numerical study of high‐intensity focused ultrasound (HIFU) in fat reduction

Numerical analysis of thermal response of tissues subjected to high intensity focused ultrasound

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