Literature DB >> 21877776

Bubble proliferation in the cavitation field of a shock wave lithotripter.

Yuri A Pishchalnikov1, James C Williams, James A McAteer.   

Abstract

Lithotripter shock waves (SWs) generated in non-degassed water at 0.5 and 2 Hz pulse repetition frequency (PRF) were characterized using a fiber-optic hydrophone. High-speed imaging captured the inertial growth-collapse-rebound cycle of cavitation bubbles, and continuous recording with a 60 fps camcorder was used to track bubble proliferation over successive SWs. Microbubbles that seeded the generation of bubble clouds formed by the breakup of cavitation jets and by bubble collapse following rebound. Microbubbles that persisted long enough served as cavitation nuclei for subsequent SWs, as such bubble clouds were enhanced at fast PRF. Visual tracking suggests that bubble clouds can originate from single bubbles.

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Year:  2011        PMID: 21877776      PMCID: PMC3195892          DOI: 10.1121/1.3609920

Source DB:  PubMed          Journal:  J Acoust Soc Am        ISSN: 0001-4966            Impact factor:   1.840


  7 in total

1.  Cavitation detection during shock-wave lithotripsy.

Authors:  Michael R Bailey; Yuri A Pishchalnikov; Oleg A Sapozhnikov; Robin O Cleveland; James A McAteer; Nathan A Miller; Irina V Pishchalnikova; Bret A Connors; Lawrence A Crum; Andrew P Evan
Journal:  Ultrasound Med Biol       Date:  2005-09       Impact factor: 2.998

2.  Why stones break better at slow shockwave rates than at fast rates: in vitro study with a research electrohydraulic lithotripter.

Authors:  Yuri A Pishchalnikov; James A McAteer; James C Williams; Irina V Pishchalnikova; R Jason Vonderhaar
Journal:  J Endourol       Date:  2006-08       Impact factor: 2.942

3.  Air pockets trapped during routine coupling in dry head lithotripsy can significantly decrease the delivery of shock wave energy.

Authors:  Yuri A Pishchalnikov; Joshua S Neucks; R Jason VonDerHaar; Irina V Pishchalnikova; James C Williams; James A McAteer
Journal:  J Urol       Date:  2006-12       Impact factor: 7.450

4.  Effect of overpressure and pulse repetition frequency on cavitation in shock wave lithotripsy.

Authors:  Oleg A Sapozhnikov; Vera A Khokhlova; Michael R Bailey; James C Williams; James A McAteer; Robin O Cleveland; Lawrence A Crum
Journal:  J Acoust Soc Am       Date:  2002-09       Impact factor: 1.840

5.  Cavitation selectively reduces the negative-pressure phase of lithotripter shock pulses.

Authors:  Yuri A Pishchalnikov; Oleg A Sapozhnikov; Michael R Bailey; Irina V Pishchalnikova; James C Williams; James A McAteer
Journal:  Acoust Res Lett Online       Date:  2005-11-03

6.  Influence of shock wave pressure amplitude and pulse repetition frequency on the lifespan, size and number of transient cavities in the field of an electromagnetic lithotripter.

Authors:  P Huber; K Jöchle; J Debus
Journal:  Phys Med Biol       Date:  1998-10       Impact factor: 3.609

7.  Effect of firing rate on the performance of shock wave lithotriptors.

Authors:  Yuri A Pishchalnikov; James A McAteer; James C Williams
Journal:  BJU Int       Date:  2008-08-14       Impact factor: 5.588
  7 in total
  18 in total

1.  Acoustic bubble removal to enhance SWL efficacy at high shock rate: an in vitro study.

Authors:  Alexander P Duryea; William W Roberts; Charles A Cain; Hedieh A Tamaddoni; Timothy L Hall
Journal:  J Endourol       Date:  2013-10-04       Impact factor: 2.942

2.  Removal of residual nuclei following a cavitation event using low-amplitude ultrasound.

Authors:  Alexander P Duryea; Charles A Cain; Hedieh A Tamaddoni; William W Roberts; Timothy L Hall
Journal:  IEEE Trans Ultrason Ferroelectr Freq Control       Date:  2014-10       Impact factor: 2.725

3.  High-speed video microscopy and numerical modeling of bubble dynamics near a surface of urinary stone.

Authors:  Yuri A Pishchalnikov; William M Behnke-Parks; Kevin Schmidmayer; Kazuki Maeda; Tim Colonius; Thomas W Kenny; Daniel J Laser
Journal:  J Acoust Soc Am       Date:  2019-07       Impact factor: 1.840

4.  Energy shielding by cavitation bubble clouds in burst wave lithotripsy.

Authors:  Kazuki Maeda; Adam D Maxwell; Tim Colonius; Wayne Kreider; Michael R Bailey
Journal:  J Acoust Soc Am       Date:  2018-11       Impact factor: 1.840

5.  An investigation of elastic waves producing stone fracture in burst wave lithotripsy.

Authors:  Adam D Maxwell; Brian MacConaghy; Michael R Bailey; Oleg A Sapozhnikov
Journal:  J Acoust Soc Am       Date:  2020-03       Impact factor: 1.840

6.  Removal of residual nuclei following a cavitation event: a parametric study.

Authors:  Alexander P Duryea; Hedieh A Tamaddoni; Charles A Cain; William W Roberts; Timothy L Hall
Journal:  IEEE Trans Ultrason Ferroelectr Freq Control       Date:  2015-09       Impact factor: 2.725

7.  Removal of residual cavitation nuclei to enhance histotripsy erosion of model urinary stones.

Authors:  Alexander P Duryea; William W Roberts; Charles A Cain; Timothy L Hall
Journal:  IEEE Trans Ultrason Ferroelectr Freq Control       Date:  2015-05       Impact factor: 2.725

8.  Acoustic Methods for Increasing the Cavitation Initiation Pressure Threshold.

Authors:  Hedieh Alavi Tamaddoni; Alexander P Duryea; Eli Vlaisavljevich; Zhen Xu; Timothy L Hall
Journal:  IEEE Trans Ultrason Ferroelectr Freq Control       Date:  2018-08-29       Impact factor: 2.725

9.  Turbulent water coupling in shock wave lithotripsy.

Authors:  Jaclyn Lautz; Georgy Sankin; Pei Zhong
Journal:  Phys Med Biol       Date:  2013-01-15       Impact factor: 3.609

10.  Cavitation-induced streaming in shock wave lithotripsy.

Authors:  Yuri A Pishchalnikov; James A McAteer
Journal:  Proc Meet Acoust       Date:  2013-05-14
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