Characterization of nonlinear ultrasound fields of 2D therapeutic arrays.

Petr V Yuldashev, Wayne Kreider, Oleg A Sapozhnikov, Navid Farr, Ari Partanen, Michael R Bailey, Vera Khokhlova
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Abstract

A current trend in high intensity focused ultrasound (HIFU) technologies is to use 2D focused phased arrays that enable electronic steering of the focus, beamforming to avoid overheating of obstacles (such as ribs), and better focusing through inhomogeneities of soft tissue using time reversal methods. In many HIFU applications, the acoustic intensity in situ can reach thousands of W/cm2 leading to nonlinear propagation effects. At high power outputs, shock fronts develop in the focal region and significantly alter the bioeffects induced. Clinical applications of HIFU are relatively new and challenges remain for ensuring their safety and efficacy. A key component of these challenges is the lack of standard procedures for characterizing nonlinear HIFU fields under operating conditions. Methods that combine low-amplitude pressure measurements and nonlinear modeling of the pressure field have been proposed for axially symmetric single element transducers but have not yet been validated for the much more complex 3D fields generated by therapeutic arrays. Here, the method was tested for a clinical HIFU source comprising a 256-element transducer array. A numerical algorithm based on the Westervelt equation was used to enable 3D full-diffraction nonlinear modeling. With the acoustic holography method, the magnitude and phase of the acoustic field were measured at a low power output and used to determine the pattern of vibrations at the surface of the array. This pattern was then scaled to simulate a range of intensity levels near the elements up to 10 W/cm2. The accuracy of modeling was validated by comparison with direct measurements of the focal waveforms using a fiber-optic hydrophone. Simulation results and measurements show that shock fronts with amplitudes up to 100 MPa were present in focal waveforms at clinically relevant outputs, indicating the importance of strong nonlinear effects in ultrasound fields generated by HIFU arrays.

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二维治疗阵列非线性超声场的特征。
目前,高强度聚焦超声(HIFU)技术的发展趋势是使用二维聚焦相控阵,以实现聚焦的电子转向、避免障碍物(如肋骨)过热的波束成形,以及使用时间反转方法更好地聚焦软组织的不均匀性。在许多 HIFU 应用中,原位声强可达数千瓦/平方厘米,从而导致非线性传播效应。在高功率输出时,病灶区域会出现冲击前沿,从而显著改变所诱导的生物效应。HIFU 的临床应用相对较新,在确保其安全性和有效性方面仍面临挑战。这些挑战的一个关键因素是缺乏在工作条件下表征非线性 HIFU 场的标准程序。针对轴对称单元件传感器提出了结合低振幅压力测量和压力场非线性建模的方法,但尚未对治疗阵列产生的复杂得多的三维场进行验证。在此,该方法针对由 256 个元素换能器阵列组成的临床 HIFU 源进行了测试。使用基于 Westervelt 方程的数值算法实现了三维全衍射非线性建模。利用声全息法,可以在低功率输出时测量声场的幅度和相位,并确定阵列表面的振动模式。然后对该模式进行缩放,以模拟元件附近高达 10 W/cm2 的一系列强度水平。通过与使用光纤水听器直接测量的焦点波形进行比较,验证了建模的准确性。模拟结果和测量结果表明,在临床相关输出的焦点波形中存在振幅高达 100 兆帕的冲击前沿,这表明了 HIFU 阵列产生的超声场中强非线性效应的重要性。
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