A mechanistic analysis of stone fracture in lithotripsy

In vitro experiments and an elastic wave model were used to analyze how stress is induced in kidney stones by lithotripsy and to test the roles of individual mechanisms-spallation, squeezing, and cavitation. Cylindrical U30 cement stones were treated in an HM-3-style lithotripter. Baffles were used...

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Bibliographic Details
Published in:The Journal of the Acoustical Society of America 2007-02, Vol.121 (2), p.1190-1202
Main Authors: Sapozhnikov, Oleg A., Maxwell, Adam D., MacConaghy, Brian, Bailey, Michael R.
Format: Article
Language:English
Subjects:
Biomechanical Phenomena
Calcium Sulfate
Humans
In Vitro Techniques
Kidney Calculi - therapy
Linear Models
Lithotripsy - methods
Models, Theoretical
Photography
Stress, Mechanical
Tensile Strength
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Summary:In vitro experiments and an elastic wave model were used to analyze how stress is induced in kidney stones by lithotripsy and to test the roles of individual mechanisms-spallation, squeezing, and cavitation. Cylindrical U30 cement stones were treated in an HM-3-style lithotripter. Baffles were used to block specific waves responsible for spallation or squeezing. Stones with and without surface cracks added to simulate cavitation damage were tested in glycerol (a cavitation suppressive medium). Each case was simulated using the elasticity equations for an isotropic medium. The calculated location of maximum stress compared well with the experimental observations of where stones fractured in two pieces. Higher calculated maximum tensile stress correlated with fewer shock waves required for fracture. The highest calculated tensile stresses resulted from shear waves initiated at the proximal corners and strengthened along the side surfaces of the stone by the liquid-borne lithotripter shock wave. Peak tensile stress was in the distal end of the stone where fracture occurred. Reflection of the longitudinal wave from the distal face of the stone-spallation-produced lower stresses. Surface cracks accelerated fragmentation when created near the location where the maximum stress was predicted.
ISSN:0001-4966
1520-8524
DOI:10.1121/1.2404894