Ultrasonic attenuation imaging in a rodent thyroid cancer model

The attenuation coefficient slope (ACS) has the potential to be used for tissue characterization and as a diagnostic ultrasound tool, hence complementing B-mode images. The ACS can be valuable for the estimation of other ultrasound parameters such as the backscatter coefficient. There is a well-known tradeoff between the precision of the estimated ACS values and the data block size used in the spectral-based techniques such as the spectral-log difference (SLD). This tradeoff limits the practical usefulness of the spectral-based attenuation imaging techniques. In this paper, the regularized SLD (RSLD) technique is presented in detail, and evaluated with simulations and experiments with physical phantoms, ex vivo and in vivo. The RSLD technique allowed decreasing estimation variance when using small data block sizes, i.e., fivefold reduction in the standard deviation of percentage error when using data block sizes larger than and more than a tenfold reduction when using data blocks. The precision improvement was obtained without sacrificing estimation accuracy (i.e., estimation bias improved in 70% of the cases by 10% of the ground truth-value on average while degraded in 30% of the cases by 3% of the ground truth-value on average). The improvements in precision allowed for better differentiation of inclusions especially when using small data blocks (i.e., smaller than ) where the contrast-to-noise ratio improved by an order of magnitude on average. The results suggest that the RSLD allows for the reconstruction of attenuation coefficient images with an improved tradeoff between spatial resolution and estimation precision.

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“…with the diffraction compensation function developed in [37] and used previously for the SLD technique in [38], i.e.,…”

Section: Diffraction Compensation Functions For the Spectral Log Diffmentioning

confidence: 99%

Regularized Spectral Log Difference Technique for Ultrasonic Attenuation Imaging

Coila

Lavarello

2018

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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“…As shown in [14], the resulting attenuation coefficient slope for each region of interest can be obtained by performing a linear fit to (1), (1) where is the distance from the transducer to the center of the window of analysis, subscripts d and p represent the distal and proximal window of the data block respectively, is the received voltage signal from the scattering volume, is the analytical BSC diffraction compensation function for singleelement transducers proposed by [15] and c is a constant term product of assuming that BSC varies in the form .…”

Section: A Qus Analytic Attenuation Estimation Methodsmentioning

confidence: 91%

“…The majority of the previously mentioned algorithms make use of a calibrated reference phantom to compensate for diffraction. In contrast, in this work the analytic attenuation estimation method for single-element transducers presented in [14] has been used. The spectral information of RF data was processed to generate attenuation maps on custom MATLAB (MathWorks, Natick, MA) software.…”

Section: A Qus Analytic Attenuation Estimation Methodsmentioning

confidence: 99%

Improving the quality of attenuation imaging using full angular spatial compounding

Zenteno

Luchies

Oelze

et al. 2014

2014 IEEE International Ultrasonics Symposium

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The quantitative imaging of attenuation coefficients slope (ACS) has the potential to improve medical diagnostics. However, attempts to characterize ACS using pulse-echo data have been limited by the large statistical variations in the estimates. Previous studies demonstrated that it is possible to extend the trade-off between variance and spatial resolution of quantitative ultrasound, spectral-based parameters by the use of full angular (i.e., 360•) spatial compounding (FASC). In the present work, the use of FASC has been extended to the estimation of ACS and its performance has been experimentally evaluated using two physical phantoms. The ACSs of the background and inclusion regions were estimated using insertion loss measurements to be 0.41 and 0.75 dB/cm/MHz for Phantom #1, and 0.54 and 1.04 dB/cm/MHz for Phantom #2, respectively. Pulseecho data were collected using a 7.5 MHz, f/4 transducer at 30 angles of view uniformly distributed between 0 and 360º. Single view ACS maps were generated using a spectral log difference method with 0.6 by 0.6 mm data blocks. The FASC images were constructed by assigning to a pixel the median of its corresponding estimates from all 30 angles of view. The reduction in the variance of the FASC estimates compared to the variance of estimates from a single view (i.e., variance averaged from the 30 single views) in the inclusion and background regions were 89.18% and 88.71% for Phantom #1 and 92.33% and 86.98% for Phantom #2. Moreover, in all the cases the estimation bias in the inclusion and background regions using FASC was lower than 9.0%. These results suggest that the variance of attenuation coefficient slope estimation can be significantly reduced without sacrificing spatial resolution by the use of full angular spatial compounding.

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