Free-Lagrange Simulations of Shock/Bubble Interaction in Shock Wave Lithotripsy

“…Pressures at such distances for propagation through water can readily be calculated using the Gilmore model [40], although this study highlights that, when doing so, it is important to assess whether the assumptions inherent in the Gilmore model are germane to the scenario being simulated (see §4). Even for propagation in water, if the bubble collapses asymmetrically as in this study, the source of the pressure wave is incorrectly modelled by the Gilmore model as being the spherically compressed gas, rather than the blast wave [15,41]. Furthermore, propagation through tissue generates higher absorption than occurs in water.…”

“…Furthermore, propagation through tissue generates higher absorption than occurs in water. There are standard methods for derating predictions made for propagation in water to give estimates of what form the pulse would take if it propagated through tissue, and these have been applied to this problem [15,41]. However, the appropriateness of using the standard method to correct for absorption by the intervening tissue has not been addressed for cases such as the shocks presented here, and this will be also discussed in §4.…”

“…However, account must be taken of absorption in the tissue and the effect of neglecting any nonlinear propagation in this way. Providentially, tissue absorption is the simpler feature to include if standard techniques are followed and are valid (a question discussed further in §4), and its inclusion reduces the importance of nonlinear propagation because high absorption rapidly attenuates the amplitude of the wave [15,41].…”

“…There are two methods for estimating the far-field emissions following linear propagation outside the control surface, and previously two numerical schemes based on the Kirchhoff and Ffowcs William-Hawkings formulations were developed and tested for this SWL problem [15,41]. The Kirchhoff method assumes that nonlinear waves are confined within the control surface, and the input parameters for the calculation of far-field acoustic emissions are compatible with linear wave propagation.…”

“…The first stage of the work developed a free-Lagrange simulation for single bubbles, which offered advantages over the existing boundary-element method of capturing blast waves, and over the Eulerian methods, in that it could follow the bubble collapse after the moment when the liquid jet formed by bubble involution impacts the downstream bubble wall [14,20,21]. Inclusion of the events after this moment into the simulation is critical because the evolution and detection of the blast wave generated by that impact (and its subsequent interaction with the kidney stone and tissue) is important both to kidney stone fracture and also to the operation of the device, which detects this blast wave in the far field via a receiver placed on the patient's torso.…”

Prediction of far-field acoustic emissions from cavitation clouds during shock wave lithotripsy for development of a clinical device

“…Pressures at such distances for propagation through water can readily be calculated using the Gilmore model [40], although this study highlights that, when doing so, it is important to assess whether the assumptions inherent in the Gilmore model are germane to the scenario being simulated (see §4). Even for propagation in water, if the bubble collapses asymmetrically as in this study, the source of the pressure wave is incorrectly modelled by the Gilmore model as being the spherically compressed gas, rather than the blast wave [15,41]. Furthermore, propagation through tissue generates higher absorption than occurs in water.…”

“…Furthermore, propagation through tissue generates higher absorption than occurs in water. There are standard methods for derating predictions made for propagation in water to give estimates of what form the pulse would take if it propagated through tissue, and these have been applied to this problem [15,41]. However, the appropriateness of using the standard method to correct for absorption by the intervening tissue has not been addressed for cases such as the shocks presented here, and this will be also discussed in §4.…”

“…However, account must be taken of absorption in the tissue and the effect of neglecting any nonlinear propagation in this way. Providentially, tissue absorption is the simpler feature to include if standard techniques are followed and are valid (a question discussed further in §4), and its inclusion reduces the importance of nonlinear propagation because high absorption rapidly attenuates the amplitude of the wave [15,41].…”

“…There are two methods for estimating the far-field emissions following linear propagation outside the control surface, and previously two numerical schemes based on the Kirchhoff and Ffowcs William-Hawkings formulations were developed and tested for this SWL problem [15,41]. The Kirchhoff method assumes that nonlinear waves are confined within the control surface, and the input parameters for the calculation of far-field acoustic emissions are compatible with linear wave propagation.…”

“…The first stage of the work developed a free-Lagrange simulation for single bubbles, which offered advantages over the existing boundary-element method of capturing blast waves, and over the Eulerian methods, in that it could follow the bubble collapse after the moment when the liquid jet formed by bubble involution impacts the downstream bubble wall [14,20,21]. Inclusion of the events after this moment into the simulation is critical because the evolution and detection of the blast wave generated by that impact (and its subsequent interaction with the kidney stone and tissue) is important both to kidney stone fracture and also to the operation of the device, which detects this blast wave in the far field via a receiver placed on the patient's torso.…”

Prediction of far-field acoustic emissions from cavitation clouds during shock wave lithotripsy for development of a clinical device

Simulations of pressure pulse–bubble interaction using boundary element method

The collapse of single bubbles and approximation of the far-field acoustic emissions for cavitation induced by shock wave lithotripsy