HIFU procedures at moderate intensities—effect of large blood vessels

A three-dimensional computational model is presented for studying the efficacy of high-intensity focused ultrasound (HIFU) procedures targeted near large blood vessels. The analysis applies to procedures performed at intensities below the threshold for cavitation, boiling and highly nonlinear propagation, but high enough to increase tissue temperature a few degrees per second. The model is based upon the linearized KZK equation and the bioheat equation in tissue. In the blood vessel the momentum and energy equations are satisfied. The model is first validated in a tissue phantom, to verify the absence of bubble formation and nonlinear effects. Temperature rise and lesion-volume calculations are then shown for different beam locations and orientations relative to a large vessel. Both single and multiple ablations are considered. Results show that when the vessel is located within about a beam width (few mm) of the ultrasound beam, significant reduction in lesion volume is observed due to blood flow. However, for gaps larger than a beam width, blood flow has no major effect on the lesion formation. Under the clinically representative conditions considered, the lesion volume is reduced about 40% (relative to the no-flow case) when the beam is parallel to the blood vessel, compared to about 20% for a perpendicular orientation. Procedures involving multiple ablation sites are affected less by blood flow than single ablations. The model also suggests that optimally focused transducers can generate lesions that are significantly larger (>2 times) than the ones produced by highly focused beams.

[1]  D. Gianfelice,et al.  MR imaging-guided focused US ablation of breast cancer: histopathologic assessment of effectiveness-- initial experience. , 2003, Radiology.

[2]  W. Dewey,et al.  Thermal dose determination in cancer therapy. , 1984, International journal of radiation oncology, biology, physics.

[3]  Zhen Xu,et al.  Investigation of intensity thresholds for ultrasound tissue erosion. , 2005, Ultrasound in medicine & biology.

[4]  N. Bush,et al.  The changes in acoustic attenuation due to in vitro heating. , 2003, Ultrasound in medicine & biology.

[5]  J Crezee,et al.  Temperature uniformity during hyperthermia: the impact of large vessels. , 1992, Physics in medicine and biology.

[6]  Jean-François Geschwind,et al.  MRI guidance of focused ultrasound therapy of uterine fibroids: early results. , 2004, AJR. American journal of roentgenology.

[7]  K Hynynen,et al.  The effect of various physical parameters on the size and shape of necrosed tissue volume during ultrasound surgery. , 1994, The Journal of the Acoustical Society of America.

[8]  Ronald A. Roy,et al.  Experimental validation of a tractable numerical model for focused ultrasound heating in flow-through tissue phantoms. , 2004, The Journal of the Acoustical Society of America.

[9]  Jinlan Huang,et al.  HEATING IN VASCULAR TISSUE AND FLOW-THROUGH TISSUE PHANTOMS INDUCED BY FOCUSED ULTRASOUND , 2002 .

[10]  Prasanna Hariharan,et al.  Radio-frequency ablation in a realistic reconstructed hepatic tissue. , 2007, Journal of biomechanical engineering.

[11]  D. G. Crighton,et al.  MODEL EQUATIONS OF NONLINEAR ACOUSTICS , 1979 .

[12]  K Hynynen,et al.  Comparison of modelled and observed in vivo temperature elevations induced by focused ultrasound: implications for treatment planning. , 2001, Physics in medicine and biology.

[13]  P. Meaney,et al.  A 3-D finite-element model for computation of temperature profiles and regions of thermal damage during focused ultrasound surgery exposures. , 1998, Ultrasound in medicine & biology.

[14]  F. Duck Physical properties of tissue , 1990 .

[15]  T. D. Mast,et al.  Bulk ablation of soft tissue with intense ultrasound: modeling and experiments. , 2005, The Journal of the Acoustical Society of America.

[16]  R. King,et al.  Development of a HIFU Phantom , 2007 .

[17]  J. Wu,et al.  Temperature elevation generated by a focused Gaussian beam of ultrasound. , 1990, Ultrasound in medicine & biology.

[18]  Numerical Solution of the Kzk Equation for Pulsed Finite Amplitude Sound Beams in Thermoviscous Fluids , 1993 .

[19]  J. Chapelon,et al.  Modeling of high-intensity focused ultrasound-induced lesions in the presence of cavitation bubbles , 2000, The Journal of the Acoustical Society of America.

[20]  R. Martin,et al.  Hemostasis of punctured blood vessels using high-intensity focused ultrasound. , 1998, Ultrasound in medicine & biology.

[21]  H. H. Pennes Analysis of tissue and arterial blood temperatures in the resting human forearm. 1948. , 1948, Journal of applied physiology.

[22]  J. Hunt,et al.  Blood flow cooling and ultrasonic lesion formation. , 1996, Medical physics.

[23]  P. Lewin,et al.  Interlaboratory evaluation of hydrophone sensitivity calibration from 0.1 to 2 MHz via time delay spectrometry. , 2004, Ultrasonics.

[24]  F A Jolesz,et al.  Determination of the optimal delay between sonications during focused ultrasound surgery in rabbits by using MR imaging to monitor thermal buildup in vivo. , 1999, Radiology.

[25]  E. Madsen,et al.  Nonlinearity parameter for tissue-mimicking materials. , 1999, Ultrasound in medicine & biology.

[26]  J A Zagzebski,et al.  Temperature dependence of ultrasonic propagation speed and attenuation in excised canine liver tissue measured using transmitted and reflected pulses. , 2004, The Journal of the Acoustical Society of America.

[27]  Yunbo Liu,et al.  High intensity focused ultrasound-induced gene activation in solid tumors. , 2006, The Journal of the Acoustical Society of America.

[28]  Xinmai Yang,et al.  A model for the dynamics of gas bubbles in soft tissue. , 2005, The Journal of the Acoustical Society of America.

[29]  H. H. Penns Analysis of tissue and arterial blood temperatures in the resting human forearm , 1948 .

[30]  R. Cleveland,et al.  Numerical simulations of heating patterns and tissue temperature response due to high-intensity focused ultrasound , 2000, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[31]  Lawrence A Crum,et al.  Effects of nonlinear propagation, cavitation, and boiling in lesion formation by high intensity focused ultrasound in a gel phantom. , 2006, The Journal of the Acoustical Society of America.