Journal ArticleDOI
Acoustic emission and sonoluminescence due to cavitation at the beam focus of an electrohydraulic shock wave lithotripter.
TLDR
It is shown that it is possible to obtain precise measurements of the time delay between the separate peaks within the signal burst detected following the secondary shock and this may, as predicted, provide a method of determining the size of bubbles remaining after the primary shock.Abstract:
The acoustic emission from cavitation in the field of an extracorporeal shock wave lithotripter has been studied using a lead zirconate titanate piezoceramic (PC4) hydrophone in the form of a 100-mm diameter focused bowl of 120-mm focal length. With this hydrophone directed at the beam focus of an electrohydraulic lithotripter radiating into water, it is possible to identify signals well above the noise level, at the 1-MHz resonance of the hydrophone, which originate at the beam focus. Light emission, attributed to sonoluminescence, is also shown to originate at the focal region of the lithotripter, and the signal obtained from a fast photomultiplier tube directed at the focus has similarities in structure and timing to the detected acoustic signals. The multiple shock emission resulting from a single discharge of an electrohydraulic source is shown to result in two separate bursts of cavitational activity separated by a period of 3–4 ms. The signal burst corresponding to the primary shock has a duration of about 600 μs with little noticeable structure. The signal burst associated with the secondary shock has a reproducible structure with two distinct peaks separated by about 200 μs depending on the shock amplitude. The timing and structure of each burst is shown to be in reasonable agreement with the theoretical predictions made by Church (1989) based on the Gilmore model of bubble dynamics. In particular, it is shown that it is possible to obtain precise measurements of the time delay between the separate peaks within the signal burst detected following the secondary shock and this may, as predicted, provide a method of determining the size of bubbles remaining after the primary shock.read more
Citations
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Journal ArticleDOI
Physics of bubble oscillations
Werner Lauterborn,Thomas Kurz +1 more
TL;DR: In this paper, the basic equations for nonlinear bubble oscillation in sound fields are given, together with a survey of typical solutions, and three stability conditions for stable trapping of bubbles in standing sound fields: positional, spherical and diffusional stability.
Journal ArticleDOI
Use of Extracorporeal Shock Waves in the Treatment of Pseudarthrosis, Tendinopathy and Other Orthopedic Diseases
TL;DR: Shock waves have changed medical therapy substantially and this new change may equal or even surpass the impact of extracorporeal shock wave lithotripsy.
Journal ArticleDOI
Cavitation Bubble Cluster Activity in the Breakage of Kidney Stones by Lithotripter Shockwaves
Yuri A. Pishchalnikov,Oleg A. Sapozhnikov,Michael R. Bailey,James C. Williams,Robin O. Cleveland,Tim Colonius,Lawrence A. Crum,Andrew P. Evan,James A. McAteer +8 more
TL;DR: Cavitation-mediated damage to stones is attributable, not to the action of solitary bubbles, but to the growth and collapse of bubble clusters.
Journal ArticleDOI
Dynamics of bubble oscillation in constrained media and mechanisms of vessel rupture in SWL.
TL;DR: Theoretical calculation of SWL-induced bubble dynamics in blood confirms that the propensity of vascular injury due to intraluminal bubble expansion increases with the tensile pressure of the lithotripter shock wave, and with the reduction of the inner diameter of the vessel.
Journal ArticleDOI
A review of the physical properties and biological effects of the high amplitude acoustic fields used in extracorporeal lithotripsy
Andrew Coleman,J.E. Saunders +1 more
TL;DR: The relatively large amplitudes and low frequencies in ESWL make it a more potent generator of transient cavitation than most other forms of medical ultrasound, and biological-effects studies with lithotripsy fields may be expected to extend the understanding of the nature of transient Cavitation.
References
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Journal ArticleDOI
Acoustic cavitation generated by an extracorporeal shockwave lithotripter
TL;DR: Evidence is presented of acoustic cavitation generated by a Dornier extracorporeal shockwave lithotripter using x-ray film, thin aluminum sheets, and relatively thick metal plates as targets, and evidence of liquid jet impacts associated with cavitation bubble collapse was observed.
Journal ArticleDOI
A theoretical study of cavitation generated by an extracorporeal shock wave lithotripter.
TL;DR: The intense acoustic wave generated at the focus of an extracorporeal shock wave lithotripter is modeled as the impulse response of a parallel RLC circuit, and the zero-order effect of gas diffusion on bubble response is included.
Journal ArticleDOI
A survey of the acoustic output of commercial extracorporeal shock wave lithotripters
Andrew Coleman,J.E. Saunders +1 more
TL;DR: Measurement problems associated with hydrophone damage and the uncertainties in the hydrophone calibration at high pressures are discussed and an estimate of the total uncertainty in the absolute measurements of the spatial-peak temporal-peak positive pressure is given as +/- 36%.
Journal ArticleDOI
Ultrasonic detection of resonant cavitation bubbles in a flow tube by their second-harmonic emissions
TL;DR: In this article, a device was constructed to detect resonant bubbles passing through it in a flowing liquid by monitoring second-harmonic responses to a low amplitude, 1.64 MHz ultrasonic field.
Journal ArticleDOI
Subharmonic and Other Low‐Frequency Emission from Bubbles in Sound‐Irradiated Liquids
TL;DR: In this paper, the authors present measurements of the acoustic emission from gas bubbles of controlled sizes "seeded" into water and glycerol-water mixtures and subjected to sound fields over a wide range of frequencies and intensities up to, and beyond, the transient cavitation threshold.