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Suppression of shocked-bubble expansion due to tissue confinement with application to shock-wave lithotripsy
1.M. R. Bailey, L. A. Crum, A. P. Evan, J. A. McAteer, J. C. Williams, Jr., O. A. Sapozhnikov, R. O. Cleveland, and T. Colonius, “Cavitation in shock wave lithotripsy,” in The Fifth International Symposium on Cavitation, Osaka, Japan, November 2003, Paper No. Cav03 OS-2-1-006.
2.A. P. Evan, L. R. Willis, J. E. Lingeman, and J. A. McAteer, “Renal trauma and the risk of long-term complications in shock wave lithotripsy,” Nephron 78, 1–8 (1998).
3.J. B. Freund, T. Colonius, and A. P. Evan, “A cumulative shear mechanism for tissue damage initiation in shock-wave lithotripsy,” Ultrasound Med. Biol. 33, 1495–1503 (2007).
4.M. Lokhandwalla, J. A. McAteer, J. C. Williams, Jr., and B. Sturtevant, “Mechanical haemolysis in shock wave lithotripsy (SWL): II. In vitro cell lysis due to shear,” Phys. Med. Biol. 46, 1245–1264 (2001).
5.D. Dalecki, C. H. Raeman, S. Z. Child, D. P. Penney, R. Mayer, and E. L. Carstensen, “The influence of contrast agents on hemorrhage produced by lithotripter fields,” Ultrasound Med. Biol. 23, 1435–1439 (1997).
6.P. Zhong, I. Cioanta, S. Zhu, F. H. Cocks, and G. M. Perminger, “Effects of tissue constraint on shock wave-induced bubble expansion in vivo,” J. Acoust. Soc. Am. 104, 3126–3129 (1998).
9.J. Cui, M. F. Hamilton, P. S. Wilson, and E. A. Zabolotskaya, “Bubble pulsations between parallel plates,” J. Acoust. Soc. Am. 119, 2067–2072 (2006).
10.J. S. Allen and R. A. Roy, “Dynamics of gas bubbles in viscoelastic fluids. II. Nonlinear viscoelasticity,” J. Acoust. Soc. Am. 108, 1640–1650 (2000).
11.S. Y. Emelianov, M. F. Hamilton, Y. A. Ilinskii, and E. A. Zabolotskaya, “Nonlinear dynamics of a gas bubble in an incompressible elastic medium,” J. Acoust. Soc. Am. 115, 581–588 (2004).
13.C. C. Church and X. Yang, “A theoretical study of gas bubble dynamics in tissue,” in Proceedings of the 17th International Symposium on Nonlinear Acoustics, edited by A. A. Atchley, V. W. Sparrow, and R. M. Keolian (American Institute of Physics, Melville, 2006), pp. 217–224.
14.T. Ye and J. L. Bull, “Microbubble expansions in a flexible tube,” J. Biomed. Eng. 128, 554–563 (2006).
15.T. Ye and J. L. Bull, “Direct numerical simulations of micro-bubble expansion in gas embolotherapy,” J. Biomed. Eng. 126, 746–759 (2004).
17.A. Hindmarsh, “LSODE. Ordinary differential equation system solver,” Lawrence Livermore National Laboratory, Technical Report No. ESTSC–000216CY0MP00, 1983.
18.R. O. Cleveland, M. R. Bailey, N. Fineberg, B. Hartenbaum, M. Lokhandwalla, G. A. McAteer, and B. Sturtevant, “Design and characterization of a research electrohydraulic lithotripter patterned after the Dornier HM3,” Rev. Sci. Instrum. 71, 2514–2525 (2000).
19.R. L. Whitmore, Rheology of the Circulation (Pergamon, Oxford, 1968).
20.E. Hrncir and J. Rosina, “Surface tension of blood,” Physiol. Res. 46, 319–321 (1997).
21.J. Rosina, E. Kvasnak, D. Suta, H. Kolarova, J. Malek, and L. Krajci, “Temperature dependence of blood surface tension,” Physiol. Res. 56 (Supplement 1), S93–S98 (2007).
22.R. L. Jamison and W. Kriz, Urinary concentrating mechanism: structure and function (Oxford University Press, New York, 1982).
23.J. B. West, K. Tsukimoto, O. Mathieu-Costello, and R. Prediletto, “Stress failure in pulmonary capillaries,” J. Appl. Physiol. 40, 1731–1742 (1991).
24.L. W. Welling, M. T. Zupka, and D. J. Welling, “Mechanical properties of basement-membrane,” News Physiol. Sci. 10, 30–35 (1995).
25.J. D. Humphrey, Cardiovascular Solid Mechanics: Cells, Tissues, and Organs (Springer, New York, 2002).
26.L. Osvaldo and H. Latta, “Interstitial cells and the renal medulla,” J. Ultrastruct. Res. 15, 589–613 (1966).
27.J. W. Melvin, R. L. Stalnaker, and V. L. Roberts, “Impact injury mechanisms in abdominal organs,” Proceedings of the 17th Stapp Car Crash Conference, SAE Trans. 730968, 115–126 (1973).
28.M. Farshad, M. Barbezat, P. Flüeler, F. Schmidlin, P. Graber, and P. Niederer, “Material characterization of the pig kidney in relation with the biomechanical analysis of renal trauma,” J. Biomech. 32, 417–425 (1999).
29.S. Nasseri, L. E. Bilston, and N. Phan-Thien, “Viscoelastic properties of pig kidney in shear, experimental results and modelling,” Rheol. Acta 41, 180–192 (2002).
30.L. A. Frizzell, E. L. Carstensen, and J. F. Dyro, “Shear properties of mammalian tissues at low megahertz frequencies,” J. Acoust. Soc. Am. 60, 1409–1411 (1977).
31.E. L. Madsen, H. J. Sathoff, and J. A. Zagzebski, “Ultrasonic shear wave properties of soft tissues and tissue like materials,” J. Acoust. Soc. Am. 74, 1346–1355 (1983).
32.S. Girnyk, A. Barannik, E. Barannik, V. Tovstiak, A. Marusenko, and V. Volokhov, “The estimation of elasticity and viscosity of soft tissues in vitro using the data of remote acoustic palpation,” Ultrasound Med. Biol. 32, 211–219 (2006).
33.X. Yang and C. C. Church, “A simple viscoelastic model for soft tissues in the frequency range ,” IEEE Trans. Ultrason. Ferroelectr. Freq. Control 53, 1404–1411 (2006).
34.C. F. Caskey, S. M. Stieger, S. Qin, P. A. Dayton, and K. W. Ferrara, “Direct observations of ultrasound microbubble contrast agent interaction with the microvessel wall,” J. Acoust. Soc. Am. 122, 1191–1200 (2007).
35.C. C. Church, “A theoretical study of cavitation generated by an extracorporeal shock wave lithotripter,” J. Acoust. Soc. Am. 86, 215–227 (1989).
36.Y. Shao, B. A. Connors, A. P. Evan, L. R. Willis, D. A. Lifshitz, and J. E. Lingeman, “Morphological changes induced in the pig kidney by extracorporeal shock wave lithotripsy,” Anat. Rec. 275A, 979–989 (2003).
37.J. Lighthill, Mathematical Biofluiddynamics (Society for Industrial and Applied Mathematics, Philadelphia, 1989).
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