An Overview of Elastography-An Emerging Branch of Medical Imaging

Sarvazyan, Armen; Hall, Timothy J.; Urban, Matthew W.; Fatemi, Mostafa; Aglyamov, Salavat R.; Garra, Brian S.

doi:10.2174/157340511798038684

Cited by 354 publications

(239 citation statements)

References 320 publications

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“…By having variations in the duration of the applied force and different measuring methods, a variety of imaging methods have been obtained, each having advantages and drawbacks [18]. A brief about the most common methods is given in the following sub-section.…”

Section: Literature Reviewmentioning

confidence: 99%

On Shear Wave Speed Estimation for Agar-Gelatine Phantom

Ahmed¹,

Salem²,

Seddik³

et al. 2016

ijacsa

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Abstract-Conventional imaging of diagnostic ultrasound is widely used. Although it makes the differences in the soft tissues echogenicities' apparent and clear, it fails in describing and estimating the soft tissue mechanical properties. It cannot portray their mechanical properties, such as the elasticity and stiffness. Estimating the mechanical properties increases chances of the identification of lesions or any pathological changes. Physicians are now characterizing the tissue's mechanical properties as diagnostic metrics. Estimating the tissue's mechanical properties is achieved by applying a force on the tissue and calculating the resulted shear wave speed. Due to the difficulty of calculating the shear wave speed precisely inside the tissue, it is estimated by analyzing ultrasound images of the tissue at a very high frame rate. In this paper, the shear wave speed is estimated using finite element analysis. A model is constructed to simulate the tissue's mechanical properties. For a generalized soft tissue model, Agar-gelatine model is used because it has properties similar to that of the soft tissue. A point force is applied at the center of the proposed model. As a result of this force, a deformation is caused. Peak displacements are tracked along the lateral dimension of the model for estimating the shear wave speed of the propagating wave using the Time-To-Peak displacement (TTP) method. Experimental results have shown that the estimated speed of the shear wave is 5.2 m/sec. The speed value is calculated according to shear wave speed equation equals about 5.7 m/sec; this means that our speed estimation system's accuracy is about 91 %, which is reasonable shear wave speed estimation accuracy with a less computational power compared to other tracking methods.

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Section: Literature Reviewmentioning

confidence: 99%

On Shear Wave Speed Estimation for Agar-Gelatine Phantom

Ahmed¹,

Salem²,

Seddik³

et al. 2016

ijacsa

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“…General reviews of elastography are provided by several authors. [61][62][63][64] It is only shear wave elastography which will be described in this paper. Shear wave elastography involves the generation of shear waves followed by measurement of their speed of propagation within tissue.…”

Section: Elastography Imagingmentioning

confidence: 99%

Recent developments in vascular ultrasound technology

Kenwright

2015

Ultrasound

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This article describes four technologies relevant to vascular ultrasound which are available commercially in 2015, and traces their origin back through the research literature. The technologies are 3D ultrasound and its use in plaque volume estimation (first described in 1994), colour vector Doppler for flow visualisation (1994), wall motion for estimation of arterial stiffness (1968), and shear wave elastography imaging of the arterial wall (2010). Overall these technologies have contributed to the understanding of vascular disease but have had little impact on clinical practice. The basic toolkit for vascular ultrasound has for the last 25 years been real-time B-mode, colour flow and spectral Doppler. What has changed over this time is improvement in image quality. Looking ahead it is noted that 2D array transducers and high frame rate imaging continue to spread through the commercial vascular ultrasound sector and both have the potential to impact on clinical practice.

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“…To complement B-mode imaging, quantitative ultrasound (QUS) explores frequency, phase, or statistical information of backscattered ultrasound signals for tissue characterization [3][4][5][6][7][8][9][10]. In the context of QUS, parameters including backscatter coefficient, acoustic attenuation, speed of sound, envelope statistics, scatterer properties, and tissue elasticity can be quantified for tissue characterization [4,11,12].…”

Section: Introductionmentioning

confidence: 99%