Structure function for high-concentration biophantoms of polydisperse scatterer sizes

Han, Aiguo; O’Brien, William D.

doi:10.1109/tuffc.2014.006629

Cited by 31 publications

(47 citation statements)

References 36 publications

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“…This linear relationship has been used to monitor the scatterer radius and/or acoustic concentration. However, the assumption of randomly distributed scatterers may not hold in concentrated cell pellet biophantoms [11] or in tumors with densely packed cells [12]. Therefore, our hypothesis is that a scattering model considering the interference effects caused by the correlations among scatterer positions (i.e.…”

Section: Introductionmentioning

confidence: 99%

High-Frequency Quantitative Ultrasound Spectroscopy of Excised Canine Livers and Mouse Tumors Using the Structure Factor Model

Muleki-Seya

Guillermin

Guglielmi

et al. 2016

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

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Three scattering models were examined for characterizing ex vivo canine livers and HT29 mouse tumors in the 10-38- and the 15-42-MHz frequency bandwidth, respectively. The spherical Gaussian model (SGM) and the fluid sphere model (FSM) that were examined are suitable for dealing with sparse media, whereas the structure factor model (SFM) is adapted for characterizing concentrated media. For the canine livers, the scatterer radius and the acoustic concentration estimated with the three models were similar and matched well the nuclear structures obtained from histological analysis (with relative errors less than 7%). These results show that the livers could be considered as a diluted medium and that the nuclei in liver could be a dominant source of scattering. For the homogeneous mouse tumors, containing mostly viable HT29 cells, scatterer radius and volume fraction estimated with the SFM showed good agreement with the whole cell structures obtained from histological analysis (with relative errors less than 15%), whereas the sparse models (the SGM and the FSM) gave no consistent quantitative ultrasound parameters. This suggests that the viable HT29 cell areas have densely packed cellular content and that the whole HT29 cell could be responsible for scattering. For the heterogeneous tumors, the hyperechogenic zones observed in the B-mode images were linked to the presence of small necrotic areas surrounded by viable HT29 cells. Comparison between sparse and concentrated models shows that these hyperechogenic zones could be considered as a concentrated medium.

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Section: Introductionmentioning

confidence: 99%

High-Frequency Quantitative Ultrasound Spectroscopy of Excised Canine Livers and Mouse Tumors Using the Structure Factor Model

Muleki-Seya

Guillermin

Guglielmi

et al. 2016

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

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“…Also, the structure function can be affected by the scatterer size distribution. Three Percus-Yevick type structure function models based on different assumptions about the scatterer size and scattering amplitude were discussed in [25]: the monodisperse model, polydisperse model I, and polydisperse model II. The assumptions for the three models are listed in Table 1.…”

Section: Structure Function Theorymentioning

confidence: 99%

“…In this paper, we will develop algorithms for estimating the structure function from the histology of biophantoms and compare the histologically estimated structure function to that estimated acoustically as was done in [25]. 3D histological data have been used by Mamou et al to model and identify scattering structures [40], [41].…”

Section: Introductionmentioning

confidence: 99%

“…Inspired by the 3DZM approach, this paper investigates the structure function using 2D histological images. Specifically, the aim is to investigate whether the acoustically estimated structure function in [25] was indeed a result of the spatial distribution of scatterers. This investigation is helpful in improving our understanding of the relationship between the backscattered data and histology.…”

Section: Introductionmentioning

confidence: 99%

“…Section IV will review the structure function results obtained acoustically for the biophantoms in [24], and present the histologically estimated results, and compare the two. The histologically estimated structure function is then compared to a polydisperse structure function model developed in [25]. The structure function results from tumors will also be presented.…”

Section: Introductionmentioning

confidence: 99%

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Structure Function Estimated From Histological Tissue Sections

Han

O’Brien

2016

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

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Ultrasonic scattering is determined by not only the properties of individual scatterers but also the correlation among scatterer positions. The role of scatterer spatial correlation is significant for dense medium, but has not been fully understood. The effect of scatterer spatial correlation may be modeled by the structure function as a frequency-dependent factor in the backscatter coefficient (BSC) expression. The structure function has been previously estimated from the BSC data. The aim of this study is to estimate the structure function from histology to test if the acoustically estimated structure function is indeed caused by the scatterer spatial distribution. Hematoxylin and eosin stained histological sections from dense cell pellet biophantoms were digitized. The scatterer positions were determined manually from the histological images. The structure function was calculated from the extracted scatterer positions using two-dimensional fast Fourier transform. The structure function obtained from histology showed reasonable agreement in the shape but not in the amplitude, compared with the structure function previously estimated from backscattered data. Fitting a polydisperse structure function model to the histologically estimated structure function yielded relatively accurate cell radius estimates (error < 15%). Further, two types of mouse tumors that have similar cell size and shape but distinct cell spatial distributions were studied, where the backscattered data were shown to be related to the cell spatial distribution through the structure function estimated from histology. In conclusion, the agreement between acoustically estimated and histologically estimated structure functions suggests that the acoustically estimated structure function is related to the scatterer spatial distribution. 1

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Quantitative ultrasound techniques for assessing thermal ablation: Measurement of the backscatter coefficient from ex vivo human liver

Rohfritsch,

Franceschini,

Dupré

et al. 2023

Medical Physics

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BackgroundUnderstanding the changes occurring in biological tissue during thermal ablation is at the heart of many current challenges in both therapy and medical imaging research.PurposeThe objective of this work is to quantitatively interpret the scattering response of human liver samples, before and after thermal ablation. We report acoustic measurements performed involving n = 21 human liver samples. Thermal ablation is achieved at temperatures between 45 and 80°C and quantification of the irreversible changes in acoustic attenuation and Backscattering Coefficient (BSC) is reported, with a particular attention to the latter.MethodsBoth attenuation coefficient and BSCs were measured in the frequency range from 10 to 52 MHz. Scans were performed before heating and after cooling down. Attenuation coefficients were calculated using spectral difference method and BSC estimated using the reference phantom method.ResultsStrong increases of attenuation coefficients and BSCs with heating temperature were observed. Quantitative ultrasonic parameters obtained with the polydisperse structure factor model (poly‐SFM)are compared to histological observations and seen to be close to hepatocyte mean diameter (HMD).ConclusionsThe results presented in this study provide a description of the impact of thermal ablation in human liver tissue on acoustic attenuation and the BSC. For the first time, quantitative agreement between the Effective Scatterer Diameter (ESD) estimated from BSC and HMD was shown, highlighting the important role of cellular network in the scattering response of the medium. This core result is an important step toward the determination of the nature of scattering sources in biological tissues.

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Structure function for high-concentration biophantoms of polydisperse scatterer sizes

Cited by 31 publications

References 36 publications

High-Frequency Quantitative Ultrasound Spectroscopy of Excised Canine Livers and Mouse Tumors Using the Structure Factor Model

High-Frequency Quantitative Ultrasound Spectroscopy of Excised Canine Livers and Mouse Tumors Using the Structure Factor Model

Structure Function Estimated From Histological Tissue Sections

Quantitative ultrasound techniques for assessing thermal ablation: Measurement of the backscatter coefficient from ex vivo human liver

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