1Department of Biomedical Engineering, Duke University, Durham, NC, USA.
Ultrason Imaging. 2014 Jan;36(1):35-54. doi: 10.1177/0161734613510287.
We present the first correction of refraction in three-dimensional (3D) ultrasound imaging using an iterative approach that traces propagation paths through a two-layer planar tissue model, applying Snell's law in 3D. This approach is applied to real-time 3D transcranial ultrasound imaging by precomputing delays offline for several skull thicknesses, allowing the user to switch between three sets of delays for phased array imaging at the push of a button. Simulations indicate that refraction correction may be expected to increase sensitivity, reduce beam steering errors, and partially restore lost spatial resolution, with the greatest improvements occurring at the largest steering angles. Distorted images of cylindrical lesions were created by imaging through an acrylic plate in a tissue-mimicking phantom. As a result of correcting for refraction, lesions were restored to 93.6% of their original diameter in the lateral direction and 98.1% of their original shape along the long axis of the cylinders. In imaging two healthy volunteers, the mean brightness increased by 8.3% and showed no spatial dependency.
我们提出了一种使用迭代方法在三维(3D)超声成像中校正折射的方法,该方法通过在 3D 中应用 Snell 定律来追踪通过两层平面组织模型的传播路径。该方法通过为几种颅骨厚度离线预先计算延迟,允许用户在相控阵成像之间切换三组延迟,从而应用于实时 3D 经颅超声成像。模拟表明,折射校正可能会提高灵敏度,减少波束转向误差,并部分恢复丢失的空间分辨率,在最大转向角度时效果最佳。通过在组织模拟体模中的亚克力板中进行成像,创建了圆柱形病变的失真图像。由于对折射进行了校正,病变在侧向方向上恢复到原始直径的 93.6%,在圆柱体的长轴方向上恢复到原始形状的 98.1%。在对两名健康志愿者进行成像时,平均亮度增加了 8.3%,并且没有空间依赖性。