Abstract
The paper considers specific features of ultrasonic visualization of gas bubbles in a liquid or a medium of like soft biological tissue type under conditions when the size of scatterers is comparable to the acoustic wavelength. It was proposed to use styrofoam specimens as the experimental model of stationary gas bubbles. Patterns of ultrasound scattering by a styrofoam sphere in water were obtained experimentally. It was shown that the measurement results agree well with the prediction of the classical theoretical model of scattering of a plane wave by a perfectly soft sphere. Several experiments were performed illustrating the specific features of visualizing millimeter-sized bubbles. A Terason commercial ultrasonic scanner was used; gelatin specimens with embedded styrofoam spheres served as the objects of study. The simulation and experimental results showed that when bubbles with diameters of <1 mm are visualized, it is impossible to measure the diameter of scatterers because bubbles of different diameters are imaged as bright spots of identical diameter, which is equal to the scanner resolution. To eliminate this difficulty, it is recommended to use the results of theoretical simulation performed in this study, which revealed a monotonic increase in the backscattered signal intensity with an increase in bubble radius. An ultrasonic visualization mode is proposed in which the brightness of scattered signals is used to differentiate between bubbles of different size.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
G. S. Kino, Acoustic Waves: Devices, Imaging and Analog Signal Analog Processing (Prentice-Hall, 1987; Mir, Moscow, 1990).
C. R. Hill, J. C. Bamber, G. R. ter Haar, Physical Principles of Medical Ultrasonics (Wiley, 2002; Fizmatlit, Moscow, 2008).
M. R. Bailey, S. G. Kargl, L. A. Crum, V. A. Khokhlova, and O. A. Sapozhnikov, Acoust. Phys. 49, 369 (2003).
A. Maxwell, O. A. Sapozhnikov, M. R. Bailey, L. A. Crum, Z. Xu, B. Fowlkes, Ch. Cain, and V. A. Khokhlova, Acoustics Today 8, 24 (2012).
A. D. Lapin, Acoust. Phys. 44, 364 (1998).
Yu. N. Makov, Acoust. Phys. 55, 547 (2009).
Ph. Morse, Vibration and Sound (MacGraw-Hill, 1948; Gos. Izd. Tekhn.-Teor. Lit., Moscow, 1949).
P. Zinin, W. Weise, O. Lobkis, and S. Boseck, Wave Motion 25, 213 (1997).
W. Weise, P. Zinin, A. Briggs, T. Wilson, and S. Boseck, J. Acoust. Soc. Am. 104, 181 (1998).
V. E. Dontsov, V. E. Nakoryakov, and B. G. Pokusaev, Acoust. Phys. 42, 689 (1996).
F. W. Kremkau, Diagnostic Ultrasound: Principles and Instruments (Saunders Elsevier, 2006).
T. L. Szabo, Diagnostic Ultrasound Imaging (Elsevier Academic, 2004).
Author information
Authors and Affiliations
Corresponding author
Additional information
Original Russian Text © E.A. Annenkova, S.A. Tsysar’, O.A. Sapozhnikov, 2016, published in Akusticheskii Zhurnal, 2016, Vol. 62, No. 2, pp. 167–177.
Rights and permissions
About this article
Cite this article
Annenkova, E.A., Tsysar’, S.A. & Sapozhnikov, O.A. Constructing ultrasonic images of soft spherical scatterers. Acoust. Phys. 62, 169–178 (2016). https://doi.org/10.1134/S1063771016020020
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1134/S1063771016020020