Title :
Numerical modeling of ultrasound imaging using contrast agents for particle image velocimetry in vivo
Author :
Mukdadi, O.M. ; Kim, H.B. ; Hertzberg, J.R. ; Shandas, R.
Author_Institution :
Dept. of Mechanical Eng., Colorado Univ., Boulder, CO, USA
Abstract :
Non-invasive in vivo medical ultrasound imaging using contrast agents requires further physical understanding of ultrasound wave propagation phenomenon in tissue and scattering from microbubbles. Cumulative nonlinearity exhibited by wave motion in tissue and local nonlinearity by microbubble dynamics are strongly influence the imaging technique and microbubble detectability. The wave propagation in tissue is studied using KZK-type parabolic evolution equation. This model considers ultrasound beam diffraction, attenuation, and tissue nonlinearity. Pressure-wave scattering from microbubbles, seeded in the blood stream, is modeled using Rayleigh-Plesset-type equation. The continuity and the radial-momentum equations of encapsulated microbubbles are employed to account for the lipid layer surrounding the microbubble. Numerical results show the effects of tissue and microbubble nonlinearities on pressure-wave propagation and scattering. These nonlinearities have a strong influence on the waveform distortion and harmonic generation. Results also show that microbubbles have stronger nonlinearity than that of tissue, and thus improves signal-to-noise ratio.
Keywords :
bioacoustics; biological tissues; biomedical ultrasonics; blood; bubbles; haemodynamics; lipid bilayers; physiological models; ultrasonic absorption; ultrasonic diffraction; ultrasonic propagation; ultrasonic scattering; KZK-type parabolic evolution equation; Rayleigh-Plesset-type equation; attenuation; blood stream; contrast agents; harmonic generation; lipid layer; noninvasive in vivo medical ultrasound imaging; numerical modeling; particle image velocimetry; radial-momentum equations; tissue nonlinearity; ultrasound beam diffraction; ultrasound wave propagation; waveform distortion; Attenuation; Biomedical imaging; Diffraction; In vivo; Motion detection; Nonlinear equations; Numerical models; Particle scattering; Rayleigh scattering; Ultrasonic imaging;
Conference_Titel :
Biomedical Imaging: Nano to Macro, 2004. IEEE International Symposium on
Print_ISBN :
0-7803-8388-5
DOI :
10.1109/ISBI.2004.1398585
