scholarly article | Q13442814 |
P2093 | author name string | Pei Zhong | |
Georgy Sankin | |||
Jaclyn Lautz | |||
P2860 | cites work | A simple method for fabricating artificial kidney stones of different physical properties | Q30450351 |
A comparison of light spot hydrophone and fiber optic probe hydrophone for lithotripter field characterization | Q30459653 | ||
Bubble proliferation in the cavitation field of a shock wave lithotripter | Q30465199 | ||
Shock wave technology and application: an update | Q30468744 | ||
Simulation of the effects of cavitation and anatomy in the shock path of model lithotripters | Q30472685 | ||
Cavitation selectively reduces the negative-pressure phase of lithotripter shock pulses | Q30486663 | ||
Control of cavitation activity by different shockwave pulsing regimes | Q31403693 | ||
Effect of escalating versus fixed voltage treatment on stone comminution and renal injury during extracorporeal shock wave lithotripsy: a prospective randomized trial | Q37657847 | ||
Improved acoustic coupling for shock wave lithotripsy | Q39827610 | ||
Modeling of interaction between therapeutic ultrasound propagation and cavitation bubbles | Q42698738 | ||
Cavitation effects during lithotripsy. Part I. Results of in vitro experiments | Q43459569 | ||
The role of stress waves and cavitation in stone comminution in shock wave lithotripsy | Q44038460 | ||
Cavitation cluster dynamics in shock-wave lithotripsy: part 1. Free field. | Q51443637 | ||
The effect of treatment strategy on stone comminution efficiency in shock wave lithotripsy. | Q51660966 | ||
A mechanistic analysis of stone fracture in lithotripsy. | Q51920796 | ||
Effect of overpressure and pulse repetition frequency on cavitation in shock wave lithotripsy. | Q53670529 | ||
The cavitation threshold of human tissue exposed to 0.2-MHz pulsed ultrasound: Preliminary measurements based on a study of clinical lithotripsy | Q61808430 | ||
Pressure waveforms generated by a Dornier extra-corporeal shock-wave lithotripter | Q69459319 | ||
A theoretical study of cavitation generated by an extracorporeal shock wave lithotripter | Q69666847 | ||
Shockwave frequency affects fragmentation in a kidney stone model | Q73074981 | ||
Does the rate of extracorporeal shock wave delivery affect stone fragmentation? | Q78213551 | ||
Stone fragmentation during shock wave lithotripsy is improved by slowing the shock wave rate: studies with a new animal model | Q78413080 | ||
Improvement of stone comminution by slow delivery rate of shock waves in extracorporeal lithotripsy | Q79373599 | ||
Comparison of conventional and step-wise shockwave lithotripsy in management of urinary calculi | Q80109916 | ||
Slow versus fast shock wave lithotripsy rate for urolithiasis: a prospective randomized study | Q81126049 | ||
Evaluation of a shock wave induced cavitation activity both in vitro and in vivo | Q81325482 | ||
Shock wave lithotripsy success determined by skin-to-stone distance on computed tomography | Q81476433 | ||
Optimization of treatment strategy used during shockwave lithotripsy to maximize stone fragmentation efficiency | Q84746772 | ||
P433 | issue | 3 | |
P304 | page(s) | 735-748 | |
P577 | publication date | 2013-01-15 | |
P1433 | published in | Physics in Medicine and Biology | Q7189694 |
P1476 | title | Turbulent water coupling in shock wave lithotripsy | |
P478 | volume | 58 |
Q30421891 | Acoustic bubble removal to enhance SWL efficacy at high shock rate: an in vitro study |
Q91938628 | Editorial Comment on: The Impact of Dust and Confinement on Fragmentation of Kidney Stones by Shockwave Lithotripsy in Tissue Phantoms by Randad et al. (From: Randad A, Ahn J, Bailey MR, et al. J Endourol 2019;33:400-406; DOI: 10.1089/end.2018.0516) |
Q38528381 | Engineering Better Lithotripters |
Q30429977 | Improving the lens design and performance of a contemporary electromagnetic shock wave lithotripter |
Q30394498 | Removal of residual nuclei following a cavitation event: a parametric study |
Search more.