Using high frequency ultrasound envelope statistics to determine scatterer number density in dilute cell solutions

Tunis, Adam S.; Baddour, Ralph E.; Czarnota, Gregory J.; Giles, Anoja; Worthington, A. E.; Sherar, Michael D.; Kolios, Michael C.

doi:10.1109/ultsym.2005.1602990

Cited by 12 publications

(14 citation statements)

References 13 publications

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“…There have also been efforts to understand scattering using approaches such as three-dimensional acoustic impedance map (3DZM) (Mamou et al, 2005;Dapore et al, 2011;Pawlicki et al, 2011), single cell scattering Falou et al, 2010), dilute cell solution (Tunis et al, 2005), isolated nuclei (Taggart et al, 2007), dense cell aggregate (Taggart et al, 2007), and numerical simulations (Doyle et al, 2009). Inspired by the physical phantoms, biophantoms likewise have been used as a technique to elucidate scattering phenomena.…”

Section: Introductionmentioning

confidence: 99%

Ultrasonic backscatter coefficient quantitative estimates from high-concentration Chinese hamster ovary cell pellet biophantoms

Han

Abuhabsah

Blue

et al. 2011

The Journal of the Acoustical Society of America

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Previous work estimated the ultrasonic backscatter coefficient (BSC) from low-concentration (volume density <3%) Chinese Hamster Ovary (CHO, 6.7-μm cell radius) cell pellets. This study extends the work to higher cell concentrations (volume densities: 9.6% to 63%). At low concentration, BSC magnitude is proportional to the cell concentration and BSC frequency dependency is independent of cell concentration. At high cell concentration, BSC magnitude is not proportional to cell concentration and BSC frequency dependency is dependent on cell concentration. This transition occurs when the volume density reaches between 10% and 30%. Under high cell concentration conditions, the BSC magnitude increases slower than proportionally with the number density at low frequencies (ka<1), as observed by others. However, what is new is that the BSC magnitude can increase either slower or faster than proportionally with number density at high frequencies (ka>1). The concentric sphere model least squares estimates show a decrease in estimated cell radius with number density, suggesting that the concentric spheres model is becoming less applicable as concentration increases because the estimated cell radius becomes smaller than that measured. The critical volume density, starting from when the model becomes less applicable, is estimated to be between 10% and 30% cell volume density.

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Section: Introductionmentioning

confidence: 99%

Ultrasonic backscatter coefficient quantitative estimates from high-concentration Chinese hamster ovary cell pellet biophantoms

Han

Abuhabsah

Blue

et al. 2011

The Journal of the Acoustical Society of America

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“…High frequency US is highly responsive to structural changes experienced by scatterers, which makes this highly applicable for monitoring therapeutic outcomes. Assessment protocols for cancer treatments have patients receive a full treatment regiment before examining the progress of the treatment results with respect to tumor size or cellular alterations [44]. Tunis et al, has used envelope statistics to quantify structural changes that transpire during apoptosis and necrosis, which has provided a viable solution to monitoring tumor response during treatment in a non-invasive procedure [44].…”

Section: Envelope Statisticsmentioning

confidence: 99%

“…Assessment protocols for cancer treatments have patients receive a full treatment regiment before examining the progress of the treatment results with respect to tumor size or cellular alterations [44]. Tunis et al, has used envelope statistics to quantify structural changes that transpire during apoptosis and necrosis, which has provided a viable solution to monitoring tumor response during treatment in a non-invasive procedure [44]. The study analyzed the statistical parameters of the Generalized Gamma model where the number density of the two solutions overlaps, the scale parameter a is larger for PC-3 cells [44].…”

Section: Envelope Statisticsmentioning

confidence: 99%

“…Tunis et al, has used envelope statistics to quantify structural changes that transpire during apoptosis and necrosis, which has provided a viable solution to monitoring tumor response during treatment in a non-invasive procedure [44]. The study analyzed the statistical parameters of the Generalized Gamma model where the number density of the two solutions overlaps, the scale parameter a is larger for PC-3 cells [44]. This is consistent with the theory that parameter a reflects the cross-section of the scatterer.…”

Section: Envelope Statisticsmentioning

confidence: 99%

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The use of optical coherence tomography envelope statistics to quantify local temperature changes in tissue-mimicking phantoms

Seevaratnam¹

2021

Preprint

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There exists a multitude of extreme thermally induced therapies for treating both benign and malignant tumors. Advancement in optics has shown prospect in clinical applications, especially monitoring oncological clinical treatments like thermal ablation. Optical coherence tomography (OCT) backscattered spectrum has demonstrated sensitivity to structural changes on the microscopic level. Envelope statistics analysis on OCT images of tissue-mimicking phantoms that are thermally modulated can provide structural information that correlates to changes in temperature. Several probability distribution functions were analyzed by looking at suitable theoretical matches to the empirical OCT data. Results indicate that the generalized gamma function was the best fit and has potential in relating the scale parameter to the size of the scatterers in the phantom. Moreover, the parameters revealed sensitivity to temperature changes, which can be further studied to understand the biological response of tissue that are exposed to extreme thermal conditions in order to improve patient care.

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“…For groupings of cells under various conditions, Tunis et al (2005a) applied envelope statistics of ultrasound backscatter to determine the scatterer number density in dilute cell solutions. However, a statistical model was used that assumed point scatterers and the study did not deal with anatomic structure of groupings of cells.…”

Section: Introductionmentioning

confidence: 99%

The measurement of ultrasound backscattering from cell pellet biophantoms and tumors ex vivo

Han

Abuhabsah

Miller

et al. 2013

The Journal of the Acoustical Society of America

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Simple scattering media fit scattering model theories much better than more complex scattering media. Tissue is much more complex as an acoustic scattering media and to date there has not been an adequate scattering model that fits it well. Previous studies evaluated the scattering characteristics of simple media (grouping of cells at various number densities) and fit them to the concentric spheres scattering model theory. This study is to increase the complexity of the media to provide insight into the acoustic scattering characteristics of tissue, and specifically two tumor types. Complementing the data from the tumors is 100% volume fraction cell pellets of the same cell lines. Cell pellets and ex vivo tumors are scanned using high-frequency single-element transducers (9-105 MHz), and the attenuation and backscatter coefficient (BSC) are estimated. BSC comparisons are made between cell pellets and tumors. The results show that the 4T1 (ATCC #CRL-2539) cell pellets and tumors have similar BSC characteristics, whereas the MAT (ATCC #CRL-1666) cell pellets and tumors have significantly different BSC characteristics. Factors that yield such differences are explored. Also, the fluid-filled sphere and the concentric spheres models are evaluated against the BSC characteristics, demonstrating that further work is required.

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Using high frequency ultrasound envelope statistics to determine scatterer number density in dilute cell solutions

Cited by 12 publications

References 13 publications

Ultrasonic backscatter coefficient quantitative estimates from high-concentration Chinese hamster ovary cell pellet biophantoms

Ultrasonic backscatter coefficient quantitative estimates from high-concentration Chinese hamster ovary cell pellet biophantoms

The use of optical coherence tomography envelope statistics to quantify local temperature changes in tissue-mimicking phantoms

The measurement of ultrasound backscattering from cell pellet biophantoms and tumors ex vivo

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