最佳基次、二次和超谐波成像的比较研究

P. van Neer, M. Danilouchkine, G. Matte, M. Voormolen, M. Verweij, N. de Jong
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引用次数: 1

摘要

许多超声方法可用于医学成像。基本成像使用与发射脉冲相同光谱带的回波。组织谐波成像(THI)利用多个基频频率,有效抑制混响、离轴和近场伪影。两种类型的THI包括二次谐波和超谐波成像(SHI)。前者使用回声的二次谐波,后者结合了第三到第五次谐波。临床研究表明,心脏基频和次谐波成像的最佳传输频率分别为3.5 MHz和1.8 MHz。由于谐波的水平是由非线性传播和衰减的平衡决定的,因此SHI的最佳频率应该更低。本研究的第一个目标是通过模拟基于适应性声纳方程的整个成像链来研究SHI的最佳发射频率。研究了两种模拟情况:第一种使用心脏组织特性,第二种基于50%心脏组织和50%血液的混合物。利用声呐方程,计算了1-2.5 MHz发射频率下15 cm范围内的第二到第五次谐波的信噪比(SNR)。对换能器的发射和接收传输进行了建模,并对其噪声进行了分析。自适应包括用轴对称KZK计算的非线性前向传播,反向传播为线性。假设在所需成像深度下产生30db动态范围的最高频率是最佳的。本研究的第二个目标是比较心脏应用的最佳基本、第二和SHI产生的光束。为此,我们对矩形孔径使用了3D KZK实现。利用心脏组织特性,SHI的最佳发射频率为1.0-1.2 MHz,在13厘米处,如果利用心脏组织/血液混合物的特性,这一频率增加到1.7 MHz。在10 cm处,最优基波、秒波和时波的- 6 dB横向波束宽度分别为1.2、1和0.7 cm。基频、次谐波和超谐波在离光束轴线1cm处的归一化强度分别为- 14、- 20和- 25 dB。心脏SHI的最佳发射频率为1.0-1.7 MHz,提供了可行的动态范围。与基频和二次谐波成像相比,SHI远场的横向分辨率更高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A comparative study of optimal fundamental, second- and superharmonic imaging
A number of ultrasound methods are available for medical imaging. Fundamental imaging uses the echoes from the same spectral band as the transmitted pulse. Tissue harmonic imaging (THI) utilizes frequencies at multiple(s) of the fundamental and effectively suppresses reverberations, and off-axis and near-field artifacts. Two types of THI comprise second- and superharmonic imaging (SHI). The former uses the second harmonic of the echoes and the latter combines the third to fifth harmonics. Clinical research showed that the optimal transmit frequency for fundamental and second harmonic cardiac imaging is 3.5 and 1.8 MHz respectively. As the level of the harmonics is determined by a balance of nonlinear propagation and attenuation, the optimal frequency for SHI is expected to be lower. The first goal of this study was to investigate the optimal transmit frequency for SHI by simulating the entire imaging chain based on an adapted SONAR equation. Two simulation cases are examined: the first uses cardiac tissue properties and the second is based on a mix of 50% cardiac tissue and 50% blood. Using the SONAR equation the signal-to-noise ratio (SNR) for the second to fifth harmonics was computed up to 15 cm for 1–2.5 MHz transmit frequencies. The transducer's transmit and receive transfer was modeled, as well as its noise. The adaptation included nonlinear forward propagation calculated with axisymmetric KZK, the backpropagation was linear. The highest frequency yielding a 30 dB dynamic range at the required imaging depth was assumed optimal. The second goal of this study was to compare the beams produced by optimal fundamental, second — and SHI for cardiac applications. To this end we used a 3D KZK implementation for rectangular apertures. The optimal transmit frequency for SHI was 1.0–1.2 MHz at 13 cm using cardiac tissue properties, this increased to 1.7 MHz if the properties of the cardiac tissue/blood mix were used. The −6 dB lateral beam width of the optimal fundamental, second- and SHI at 10 cm was 1.2, 1 and 0.7 cm respectively. The normalized intensity 1 cm off the beam axis was −14, −20 and −25 dB for the fundamental, second harmonic and superharmonic respectively. The optimal transmit frequency for cardiac SHI is 1.0–1.7 MHz providing a feasible dynamic range. The lateral resolution of SHI in the far field is higher compared to fundamental and second harmonic imaging.
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