Estimation of Backscatter Coefficients Using an <i>In Situ</i> Calibration Source

Nguyen, Trong; Tam, Alex; Minh, N.; Oelze, Michael L.

doi:10.1109/tuffc.2019.2944305

Cited by 8 publications

(3 citation statements)

References 33 publications

(33 reference statements)

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“…The normalized power spectrum is estimated through the calibration of the system with a reference signal, which can be acquired through several means, for example, planar reflector method, 12 reference phantom method, 13 or an in situ calibration target. 14,15 These methods account for system-related signals and settings. To estimate the normalized power spectrum requires access to time domain signals.…”

Section: Introductionmentioning

confidence: 99%

Spectral-based Quantitative Ultrasound Imaging Processing Techniques: Comparisons of RF Versus IQ Approaches

Liu,

Kou,

Zhao

et al. 2024

Ultrason Imaging

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Quantitative ultrasound (QUS) is an imaging technique which includes spectral-based parameterization. Typical spectral-based parameters include the backscatter coefficient (BSC) and attenuation coefficient slope (ACS). Traditionally, spectral-based QUS relies on the radio frequency (RF) signal to calculate the spectral-based parameters. Many clinical and research scanners only provide the in-phase and quadrature (IQ) signal. To acquire the RF data, the common approach is to convert IQ signal back into RF signal via mixing with a carrier frequency. In this study, we hypothesize that the performance, that is, accuracy and precision, of spectral-based parameters calculated directly from IQ data is as good as or better than using converted RF data. To test this hypothesis, estimation of the BSC and ACS using RF and IQ data from software, physical phantoms and in vivo rabbit data were analyzed and compared. The results indicated that there were only small differences in estimates of the BSC between when using the original RF, the IQ derived from the original RF and the RF reconverted from the IQ, that is, root mean square errors (RMSEs) were less than 0.04. Furthermore, the structural similarity index measure (SSIM) was calculated for ACS maps with a value greater than 0.96 for maps created using the original RF, IQ data and reconverted RF. On the other hand, the processing time using the IQ data compared to RF data were substantially less, that is, reduced by more than a factor of two. Therefore, this study confirms two things: (1) there is no need to convert IQ data back to RF data for conducting spectral-based QUS analysis, because the conversion from IQ back into RF data can introduce artifacts. (2) For the implementation of real-time QUS, there is an advantage to convert the original RF data into IQ data to conduct spectral-based QUS analysis because IQ data-based QUS can improve processing speed.

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Section: Introductionmentioning

confidence: 99%

Spectral-based Quantitative Ultrasound Imaging Processing Techniques: Comparisons of RF Versus IQ Approaches

Liu,

Kou,

Zhao

et al. 2024

Ultrason Imaging

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“…where W bead ( f , ) and σ bead ( f ) are the bead power spectrum and BSC (23). Attenuation and transmission losses in the tissue layers, which are approxi-mately the same for the bead, are eliminated by division.…”

Section: Introductionmentioning

confidence: 99%

“…To overcome the transmission and attenuation loss problem, (23) pro-posed an in situ reference method. The in situ reference, i.e., a small metal bead, involves utilizing a reference that is already contained within the sam-ple that is being characterized.…”

Section: Introductionmentioning

confidence: 99%

In vivovalidation of anin situcalibration bead as a reference for backscatter coefficient calculation

Zhao,

Czarnota,

Park

et al. 2024

Preprint

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Objectives: The study aims to assess the capability of Quantitative Ultrasound (QUS) based on the backscatter coefficient (BSC) for classifying disease states, such as breast cancer response to neoadjuvant chemotherapy and quantifying fatty liver disease. We evaluate the effectiveness of an in situ titanium (Ti) bead as a reference target in calibrating the system and mitigating attenuation and transmission loss effects on BSC estimation. Methods: Traditional BSC estimation methods require external references for calibration, which do not account for ultrasound attenuation or transmission losses through tissues. To address this issue, we use an in situ titanium (Ti) bead as a reference target, because it can be used to calibrate the system and mitigate the attenuation and transmission loss effects on estimation of the BSC. The capabilities of the in situ calibration approach were assessed by quantifying consistency of BSC estimates from rabbit mammary tumors (N = 21). Specifically, mammary tumors were grown in rabbits and when a tumor reached 1 cm or greater in size, a 2-mm Ti bead was implanted into the tumor as a radiological marker and a calibration source for ultrasound. Three days later, the tumors were scanned with a L-14/5 38 array transducer connected to a SonixOne scanner with and without a slab of pork belly placed on top of the tumors. The pork belly acted as an additional source of attenuation and transmission loss. QUS parameters, specifically effective scatterer diameter (ESD) and effective acoustic concentration (EAC), were calculated using calibration spectra from both an external reference phantom and the Ti bead. Results: For ESD estimation, the 95% confidence interval between measurements with and without the pork belly layer was (6.0,27.4) using the in situ bead and (114, 135.1) with the external reference phantom. For EAC estimation, the 95% confidence interval were (-8.1, 0.5) for the bead and (-41.5, -32.2) for the phantom. These results indicate that the in situ bead method shows reduced bias in QUS estimates due to intervening tissue losses. Conclusions: The use of an in situ Ti bead as a radiological marker not only serves its traditional role but also effectively acts as a calibration target for QUS methods. This approach accounts for attenuation and transmission losses in tissue, resulting in more accurate QUS estimates and offering a promising method for enhanced disease state classification in clinical settings.

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Quantitative Ultrasound: Experimental Implementation

Oelze

2023

Advances in Experimental Medicine and Biology

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Estimation of Backscatter Coefficients Using an In Situ Calibration Source

Cited by 8 publications

References 33 publications

Spectral-based Quantitative Ultrasound Imaging Processing Techniques: Comparisons of RF Versus IQ Approaches

Spectral-based Quantitative Ultrasound Imaging Processing Techniques: Comparisons of RF Versus IQ Approaches

In vivovalidation of anin situcalibration bead as a reference for backscatter coefficient calculation

Quantitative Ultrasound: Experimental Implementation

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