Title :
Quantitative assessment of cavitation during therapeutic ultrasound application
Author :
Jochle, K. ; Debus, J. ; Huber, P. ; Werner, A. ; Jenne, J. ; Lorenz, W.J.
fDate :
Oct. 31 1994-Nov. 3 1994
Abstract :
The object of our investigation is the interaction of pulsed high energy ultrasound with biological tissues. The generation of transient cavities seems to be the dominant non thermal mechanism for ultrasound tissue interaction. To detect events of cavitation on line in biological tissues, we constructed two cavitation detection systems, an optical and an acoustical method. By means of the optical system called laser scattering method we were able to monitor bubble dynamics in transparent liquids in a very reliable way. We used this method to verify the interpretation of acoustic echo signals received by means of the transducer. Using the acoustical method called echo analysis we were able to prove the existence of transient cavities in biological tissues, locate the bubbles and quantify their life span
Keywords :
biological effects of acoustic radiation; biomedical ultrasonics; bubbles; cavitation; echo; light scattering; nonlinear acoustics; radiation therapy; ultrasonic effects; ultrasonic transducers; acoustic echo signals; acoustical method; biological tissues; bubble dynamics; cavitation; cavitation detection systems; laser scattering method; life span; nonthermal mechanism; optical method; pulsed high energy ultrasound; quantitative assessment; therapeutic ultrasound application; transducer; transient cavities; transparent liquids; ultrasound tissue interaction; Acoustic radiation effects; Biological effects of acoustic radiation; Biological tissues; Biomedical applications of acoustic radiation; Biomedical transducers; Echo interference; Nonlinear acoustics; Optical scattering;
Conference_Titel :
Ultrasonics Symposium, 1994. Proceedings., 1994 IEEE
Conference_Location :
Cannes, France
Print_ISBN :
0-7803-2012-3
DOI :
10.1109/ULTSYM.1994.401953
