Shear strain elastography

2002 IEEE Ultrasonics Symposium, 2002. Proceedings. Pub Date : 2002-10-08 DOI:10.1109/ULTSYM.2002.1192671

F. Viola, W. Walker

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引用次数: 7

Abstract

In the breast, prostate and other organs increased tissue stiffness is often associated with the presence of disease. While palpation remains widely used, it has limited sensitivity which is highly dependent upon the skill of the clinician. To overcome this and other limitations a variety of automated approaches have been developed in recent years. These techniques generate tissue deformation by applying acoustic radiation force internally, shear waves superficially, or axial compression. In this paper we propose an alternate approach for elasticity imaging. A shear deformation is applied to the tissue surface. Ultrasound images obtained before and after shear application are processed to yield images of shear strain. We tested this method experimentally on custom acrylamide gel phantoms using a Philips SONOS 5500 imaging system. The phantoms consisted of a 5% acrylamide background with 15% acrylamide inclusions. 50 /spl mu/m sephadex spheres were used in the background and inclusion to introduce ultrasonic scattering. 4% shear rates were generated by translating the upper surface of the 5 cm thick phantoms by 2.0 mm. The shear strains observed within the inclusions of each phantom were roughly one third those seen in the background region. As anticipated, little axial deformation was observed. Experimentally obtained shear strain images clearly delineate the inclusions with few artifacts, although some noise is visible. This noise undoubtedly arises from jitter in the lateral displacement estimates. Theoretical analysis suggests that signal decorrelation under lateral shear will be very small. This, coupled with the minimal artifacts visible in the shear strain images may make shear elastography an attractive alternative to techniques.

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剪切应变弹性学

在乳腺、前列腺和其他器官中，组织僵硬度的增加通常与疾病的存在有关。虽然触诊仍然广泛使用，但它的灵敏度有限，这高度依赖于临床医生的技能。为了克服这个和其他限制，近年来开发了各种自动化方法。这些技术通过内部施加声辐射力、表面施加剪切波或轴向压缩来产生组织变形。在本文中，我们提出了弹性成像的另一种方法。对组织表面施加剪切变形。对剪切应用前后获得的超声图像进行处理，得到剪切应变图像。我们使用飞利浦SONOS 5500成像系统对定制丙烯酰胺凝胶模型进行了实验测试。幻影由5%丙烯酰胺背景和15%丙烯酰胺内含物组成。采用50 /spl μ m /m的葡聚糖球作为背景和夹杂物，引入超声散射。将5 cm厚的幻影上表面平移2.0 mm，产生4%的剪切速率。在每个幻影的内含物中观察到的剪切应变大约是背景区域中所见的剪切应变的三分之一。正如预期的那样，观察到很少的轴向变形。实验获得的剪切应变图像清晰地描绘了夹杂物，几乎没有伪影，尽管一些噪声是可见的。这种噪声无疑是由侧向位移估计中的抖动引起的。理论分析表明，侧向剪切作用下的信号去相关很小。这一点，加上在剪切应变图像中可见的最小伪影，可能使剪切弹性成像成为一种有吸引力的替代技术。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2002 IEEE Ultrasonics Symposium, 2002. Proceedings.

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