DocumentCode
1244417
Title
Propagation of shear waves generated by a modulated finite amplitude radiation force in a viscoelastic medium
Author
Giannoula, Alexia ; Cobbold, Richard S C
Author_Institution
Inst. of Biomater. & Biomed. Eng., Univ. of Toronto, Toronto, ON
Volume
56
Issue
3
fYear
2009
fDate
3/1/2009 12:00:00 AM
Firstpage
575
Lastpage
588
Abstract
An effective way to generate localized narrow-band low-frequency shear waves within tissue noninvasively, is by the modulated radiation force, resulting from the interference of two confocal quasi-CW ultrasound beams of slightly different frequencies. By using approximate viscoelastic Green´s functions, investigations of the properties of the propagated shear-field component at the fundamental modulation frequency were previously reported by our group. However, high-amplitude source excitations may be needed to increase the signal-to-noise-ratio for shear-wave detection in tissue. This paper reports a study of the generation and propagation of dynamic radiation force components at harmonics of the modulation frequency for conditions that generally correspond to diagnostic safety standards. We describe the propagation characteristics of the resulting harmonic shear waves and discuss how they depend on the parameters of nonlinearity, focusing gain, and absorption. For conditions of high viscosity (believed to be characteristic of soft tissue) and higher modulation frequencies, the approximate shear wave Green´s function is inappropriate. A more exact viscoelastic Green´s function is derived in k-space, and using this, it is shown that the lowpass and dispersive effects, associated with a Voigt model of tissue, are more accurately represented. Finally, it is shown how the viscoelastic properties of the propagating medium can be estimated, based on several spectral components of the shear wave spectrum.
Keywords
Green´s function methods; biological tissues; biomechanics; elastic waves; viscoelasticity; viscosity; Green´s functions; Voigt model; confocal quasi-CW ultrasound beams; diagnostic safety standards; dispersive effect; finite amplitude radiation force; harmonic shear waves; high-amplitude source excitations; low-pass effect; modulation frequency; signal-to-noise ratio; tissue; viscoelastic medium; viscosity; Amplitude modulation; Elasticity; Frequency modulation; Green´s function methods; Interference; Narrowband; Optical modulation; Signal to noise ratio; Ultrasonic imaging; Viscosity; Algorithms; Computer Simulation; Elasticity Imaging Techniques; Least-Squares Analysis; Models, Statistical; Models, Theoretical; Pressure; Temperature; Viscosity;
fLanguage
English
Journal_Title
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
Publisher
ieee
ISSN
0885-3010
Type
jour
DOI
10.1109/TUFFC.2009.1074
Filename
4816065
Link To Document