scholarly article | Q13442814 |
P2093 | author name string | Ohl CD | |
Arora M | |||
Junge L | |||
P2860 | cites work | Watersheds in digital spaces: an efficient algorithm based on immersion simulations | Q29013909 |
Control of cavitation activity by different shockwave pulsing regimes | Q31403693 | ||
The mechanisms of stone fragmentation in ESWL. | Q34276849 | ||
In vivo detection of ultrasonically induced cavitation by a fibre-optic technique | Q36716650 | ||
Use of a dual-pulse lithotripter to generate a localized and intensified cavitation field | Q39580450 | ||
The role of stress waves and cavitation in stone comminution in shock wave lithotripsy | Q44038460 | ||
Mechanical haemolysis in shock wave lithotripsy (SWL): II. In vitro cell lysis due to shear | Q46090344 | ||
Cavitation inception on microparticles: a self-propelled particle accelerator | Q49246596 | ||
Full-wave modeling of therapeutic ultrasound: nonlinear ultrasound propagation in ideal fluids | Q50251252 | ||
Cell detachment method using shock-wave-induced cavitation. | Q51727424 | ||
A dual passive cavitation detector for localized detection of lithotripsy-induced cavitation in vitro. | Q52080465 | ||
Modeling of an electrohydraulic lithotripter with the KZK equation. | Q52208642 | ||
Effect of overpressure and pulse repetition frequency on cavitation in shock wave lithotripsy. | Q53670529 | ||
Minimal static excess pressure minimises the effect of extracorporeal shock waves on cells and reduces it on gallstones. | Q53976391 | ||
A model of extracorporeal shock wave action: tandem action of shock waves | Q68034257 | ||
A theoretical study of cavitation generated by an extracorporeal shock wave lithotripter | Q69666847 | ||
Detection of acoustic emission from cavitation in tissue during clinical extracorporeal lithotripsy | Q73000808 | ||
Improvement of stone fragmentation during shock-wave lithotripsy using a combined EH/PEAA shock-wave generator-in vitro experiments | Q73693860 | ||
Dual-pulse lithotripter accelerates stone fragmentation and reduces cell lysis in vitro | Q73702646 | ||
Dynamics of bubble oscillation in constrained media and mechanisms of vessel rupture in SWL | Q73734111 | ||
Controlled, forced collapse of cavitation bubbles for improved stone fragmentation during shock wave lithotripsy | Q73873310 | ||
Shock wave-inertial microbubble interaction: methodology, physical characterization, and bioeffect study | Q74630228 | ||
Suppression of large intraluminal bubble expansion in shock wave lithotripsy without compromising stone comminution: methodology and in vitro experiments | Q77474466 | ||
Tandem shock wave cavitation enhancement for extracorporeal lithotripsy | Q78642547 | ||
P433 | issue | 6 | |
P304 | page(s) | 827-839 | |
P577 | publication date | 2005-06-01 | |
P1433 | published in | Ultrasound in Medicine and Biology | Q2260380 |
P1476 | title | Cavitation cluster dynamics in shock-wave lithotripsy: part 1. Free field. | |
P478 | volume | 31 |
Q30455127 | An efficient treatment strategy for histotripsy by removing cavitation memory |
Q30462963 | Cavitation clouds created by shock scattering from bubbles during histotripsy. |
Q30486663 | Cavitation selectively reduces the negative-pressure phase of lithotripter shock pulses |
Q99557849 | Cavitation-induced streaming in shock wave lithotripsy |
Q56990490 | Collective oscillations in bubble clouds |
Q86440341 | Combined short and long-delay tandem shock waves to improve shock wave lithotripsy according to the Gilmore-Akulichev theory |
Q89576624 | Confocal lens focused piezoelectric lithotripter |
Q30489829 | Effects of acoustic parameters on bubble cloud dynamics in ultrasound tissue erosion (histotripsy) |
Q50526827 | Enhanced shock wave-assisted transformation of Escherichia coli. |
Q51039381 | Impact of microbubbles on shock wave-mediated DNA uptake in cells in vitro. |
Q30429977 | Improving the lens design and performance of a contemporary electromagnetic shock wave lithotripter |
Q50180957 | Is reproducibility inside the bag? Special issue fundamentals and applications of sonochemistry ESS-15. |
Q90366200 | Kriging model to study the dynamics of a bubble subjected to tandem shock waves as used in biomedical applications |
Q42698738 | Modeling of interaction between therapeutic ultrasound propagation and cavitation bubbles |
Q51582644 | Modified shock waves for extracorporeal shock wave lithotripsy: a simulation based on the Gilmore formulation. |
Q30386322 | Noninvasive thrombolysis using microtripsy: a parameter study. |
Q30478520 | Noninvasive thrombolysis using pulsed ultrasound cavitation therapy - histotripsy |
Q30489834 | Optical and acoustic monitoring of bubble cloud dynamics at a tissue-fluid interface in ultrasound tissue erosion |
Q47315852 | Relationship between plasmid size and shock wave-mediated bacterial transformation |
Q30395614 | Removal of residual cavitation nuclei to enhance histotripsy fractionation of soft tissue. |
Q30429243 | Removal of residual nuclei following a cavitation event using low-amplitude ultrasound |
Q30394498 | Removal of residual nuclei following a cavitation event: a parametric study |
Q30499618 | Sonoporation from jetting cavitation bubbles |
Q51059226 | Suppressing bubble shielding effect in shock wave lithotripsy by low intensity pulsed ultrasound. |
Q61825854 | The acceleration of solid particles subjected to cavitation nucleation |
Q30443265 | Turbulent water coupling in shock wave lithotripsy |
Search more.