Image based registration techniques were developed, evaluated, and applied to 2D and 3D ultrasound (US) imaging in the context of deformation and aberration detection and correction. The specific applications demonstrated here include 3D compounding, generation of extended fields of view, and sound speed estimation. Despite the enormous clinical importance that diagnostic US has gained over more than four decades, and despite the fact that advances in software development and computer technology have made image registration a widely studied and moderately applied technique in other medical imaging modalities, US and image registration have rarely been combined in research or clinical application. We will show that not only can some image registration methods be transferred from other imaging modalities and adjusted to operate on US images, but also that registration can overcome or greatly ameliorate some of the existing limitations of US imaging.; A nonlinear registration algorithm developed specifically for ultrasound showed registration accuracy of 0.2 mm in volumes with synthetic deformations, 0.3 mm in phantom experiments, and 0.6 mm in vivo. Extended high-resolution ultrasound volumes with lateral extents of over 10 cm were created by fusing together 3 or 4 individual volumes, using image registration in the areas of overlap. 3D compounding in the out-of-plane direction was achieved by registration of US volumes obtained from different look directions. Examples of compounding in phantoms and in vivo show increased contrast/noise and better visualization of specular reflectors.; Image-based estimates of the average sound speed in the field of view were obtained using registration of steered 2D US images. The accuracy of the estimates was improved by including simulations of the sound field generated by the array. Evaluated over a range of sound speeds from 1490 to 1560 m/s in a custom-made phantom, the simulation results reduced the RMS deviation between the estimates and reference measurements from 0.3% to 0.1%. Using accurate estimates of the average sound speed in the beamforming process can effectively eliminate the contribution of gross sound speed errors to the overall phase aberrations.
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机译:基于图像的配准技术已开发,评估,并在变形,像差检测和校正的情况下应用于2D和3D超声(US)成像。此处演示的特定应用包括3D复合,扩展视场的生成和声速估计。尽管美国诊断技术在过去的40多年中已经获得了巨大的临床重视,并且尽管软件开发和计算机技术的进步使图像配准成为了在其他医学成像方式中被广泛研究和应用的技术,但是美国和图像配准已经很少结合研究或临床应用。我们将证明,不仅某些图像配准方法可以从其他成像方式中转移出来并进行调整以在美国图像上运行,而且配准可以克服或大大改善美国成像的一些现有局限性。专为超声开发的非线性配准算法显示,配准精度为0.2 mm(具有合成变形),体模实验为0.3 mm,体内为0.6 mm。使用重叠区域中的图像配准,通过将3或4个单独的体积融合在一起,创建了横向扩展范围超过10 cm的扩展高分辨率超声体积。通过记录从不同外观方向获得的美国体积,可以实现面外方向的3D复合。幻影和体内复合的例子显示出增加的对比度/噪声和更好的镜面反射器可视化。使用转向的2D US图像配准可获得基于图像的平均声速估计值。通过包括对阵列生成的声场的仿真,可以提高估计的准确性。在定制模型中,在1490至1560 m / s的声速范围内进行了评估,仿真结果将估算值与参考测量值之间的RMS偏差从0.3%降低到0.1%。在波束形成过程中使用平均声速的准确估计可以有效消除总声速误差对整体相位像差的影响。
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