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RAS PhysicsАкустический журнал Acoustical Physics

  • ISSN (Print) 0320-7919
  • ISSN (Online) 3034-5006

Effect of the diameter of central opening on nonlinear acoustic field characteristics of high-intensity focused ultrasound transducers

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PII
S30345006S0320791925030040-1
DOI
10.7868/S3034500625030040
Publication type
Article
Status
Published
Authors
F.A. Nartov
  • Affiliation: Lomonosov Moscow State University, Faculty of Physics
M.M. Karzov
  • Affiliation: Lomonosov Moscow State University, Faculty of Physics
V.A. Khokhlov
  • Affiliation: Lomonosov Moscow State University, Faculty of Physics
Volume/ Edition
Volume 71 / Issue number 3
Pages
360-371
Abstract
The work analyzes the effect of the size of a central opening in a spherical single-element transducer with uniform oscillatory velocity distribution on its surface on the manifestation of nonlinear effects during focusing of the generated ultrasonic beam. It is shown that the presence of a central opening significantly affects the parameters of the nonlinear field in the focal region, leads to a higher effective focusing angle and, as a result, to higher levels of peak positive pressure and characteristic rupture amplitudes in the focal profile.
Keywords
нелинейное акустическое поле фокусированный ультразвук эквивалентный источник центральное отверстие параметры поля в фокусе
Date of publication
08.12.2025
Year of publication
2025
Number of purchasers
0
Views
20

References

  1. 1. Гаврилов Л.Р. Фокусированный ультразвук высокой интенсивности в медицине. М.: Фазис, 2013.
  2. 2. Бэйли М.Р., Хохлова В.А., Сапожников О.А., Каргл С.Г., Крам Л.А. Физические механизмы воздействия терапевтического ультразвука на биологическую ткань // Акуст. журн. 2003. Т. 49. № 4. С. 437–464.
  3. 3. Xu Z., Khokhlova T.D., Cho C.S., Khokhlova V.A. Histotripsy: a method for mechanical tissue ablation with ultrasound // Annu. Rev. Biomed. Eng. 2024. V. 26. P. 141–167.
  4. 4. Williams R.P., Simon J.C., Khokhlova V.A., Sapozhnikov O.A., Khokhlova T.D. The histotripsy spectrum: differences and similarities in techniques and instrumentation // Int. J. of Hyperthermia. 2023. V. 40. № 1. P. 1–19.
  5. 5. Kim Y.S., Keserci B., Partanen A., Rhim H., Lim H.K., Park M.J., Köhler M.O. Volumetric MR-HIFU ablation of uterine fibroids: role of treatment cell size in the improvement of energy efficiency // Eur. J. Radiol. 2012. V. 81 № 11. P. 3652–3659.
  6. 6. Ramaekers P., De Greef M., Van Breugel J.M.M., Moonen C.T.W., Ries M. Increasing the HIFU ablation rate through an MRI-guided sonication strategy using shock waves: feasibility in the in vivo porcine liver // Phys. Med. Biol. 2016. V. 61. P. 1057–1077.
  7. 7. Kennedy J., Wu F., Ter Haar G., Gleeson F., Phillips R., Middleton M. and Cranston D. // Ultrasonics. 2004. V. 42. P. 931–935.
  8. 8. Андрияхина Ю.С., Карзова М.М., Юлдашев П.В., Хохлова В.А. Ускорение тепловой абляции объемов биологической ткани с использованием фокусированных ультразвуковых пучков с ударными фронтами // Акуст. журн. 2019. Т. 65. № 2. С. 147–157.
  9. 9. Пестова П.А., Карзова М.М., Юлдашев П.В., Хохлова В.А. Использование фокусированных ударно-волновых пучков для подавления эффектов диффузии при объемной тепловой абляции биоткани // Акуст. журн. 2023. Т. 69. № 4. С. 417–429.
  10. 10. Canney M.S., Khokhlova V.A., Bessonova O.V., Bailey M.R., Crum L.A. Shock-induced heating and millisecond boiling in gels and tissue due to high intensity focused ultrasound // Ultrasound Med. Biol. 2010. V. 36. № 2. P. 250–267.
  11. 11. Bawiec C.R., Khokhlova T.D., Sapozhnikov O.A., Rosnitskiy P.B., Cunitz B.W., Ghanem M.A., Hunter C., Kreider W., Schade G.R., Yuldashev P.V., Khokhlova V.A. A prototype therapy system for boiling histotripsy in abdominal targets based on a 256-element spiral array // IEEE Trans. Ultrason. Ferroelect. Freq. Contr. 2021. V. 68. № 5. P. 1496–1510.
  12. 12. Bobkova S., Gavrilov L., Khokhlova V., Shaw A., Hand J. Focusing of high-intensity ultrasound through the rib cage using a therapeutic random phased array // Ultrasound Med. Biol. 2010. V. 36. № 6. P. 888–906.
  13. 13. Karzova M.M., Kreider W., Partanen A., Khokhlova T.D., Sapozhnikov O.A., Yuldashev P.V., Khokhlova V.A. Comparative characterization of nonlinear ultrasound fields generated by Sonalleve V1 and V2 MR-HIFU systems // IEEE Trans. Ultrason. Ferroelect. Freq. Contr. 2023. V. 70. № 6. P. 521–537.
  14. 14. Khokhlova T.D., Schade G.R., Wang Y.N., Buravkov S.V., Chernikov V.P., Simon J.C., Starr F., Maxwell A.D., Bailey M.R., Kreider W., Khokhlova V.A. Pilot in vivo studies on transcutaneous boiling histotripsy in porcine liver and kidney // Scientific reports. 2019. V. 9. P. 20176.
  15. 15. Tsysar S.A., Rosnitskiy P.B., Asfandiyarov S.A., Petrosyan S.A., Khokhlova V.A., Sapozhnikov O.A. Phase correction of the channels of a fully populated randomized multielement therapeutic array using the acoustic holography method // Acoust. Phys. 2024. V. 70. № 1. P. 82–89.
  16. 16. Maxwell A.D., Yuldashev P.V., Kreider W., Khokhlova T.D., Schade G.R., Hall T.L., Sapozhnikov O.A., Bailey M.R., Khokhlova V.A. A prototype therapy system for transcutaneous application of boiling histotripsy // IEEE Trans. Ultrason. Ferroelect. Freq. Contr. 2017. V. 64. № 10. P. 1542–1557.
  17. 17. Rosnitskiy P.B., Yuldashev P.V., Sapozhnikov O.A., Maxwell A.D., Kreider W., Bailey M.R., Khokhlova V.A. Design of HIFU transducers for generating specified nonlinear ultrasound fields // IEEE Trans. Ultrason. Ferroelect. Freq. Contr. 2017. V. 64. № 2. P. 374–390.
  18. 18. Canney M.S., Bailey M.R., Crum L.A., Khokhlova V.A., Sapozhnikov O.A. Acoustic characterization of high intensity focused ultrasound fields: A combined measurement and modeling approach // J. Acoust. Soc. Amer. 2008. № 4. P. 2406–2420.
  19. 19. Sapozhnikov O.A., Tsysar S.A., Khokhlova V.A., Kreider W. Acoustic holography as a metrological tool for characterizing medical ultrasound sources and fields // J. Acoust. Soc. Amer. 2015. V. 138. № 3. P. 1515–1532.
  20. 20. Kreider W., Yuldashev P.V., Sapozhnikov O.A., Farr N., Partanen A., Bailey M.R., Khokhlova V.A. Characterization of a multi-element clinical HIFU system using acoustic holography and nonlinear modeling // IEEE Trans. Ultrason. Ferroelectr. Freq. Control. 2013. V. 60. № 8. P. 1683–1698.
  21. 21. Karzova M.M., Yuldashev P.V., Sapozhnikov O.A., Khokhlova V.A., Cunitz B.W., Kreider W., Bailey M.R. Shock formation and nonlinear saturation effects in the ultrasound field of a diagnostic curvilinear probe // J. Acoust. Soc. Am. 2017. V. 141. № 4. P. 2327–2337.
  22. 22. Юлдашев П.В., Хохлова В.А. Моделирование трехмерных нелинейных полей ультразвуковых терапевтических решеток // Акуст. журн. 2011. Т. 57. № 3. С. 337−347.
  23. 23. Gu J., Jing Y., Modeling of wave propagation for medical ultrasound: A review // IEEE Trans. Ultrason. Ferroelectr. Freq. Control. 2015. V. 62. № 11. P. 1979–1993.
  24. 24. Soneson J.E. A user-friendly software package for HIFU simulation // Proc. AIP Conf. 2009. V. 1113. № 1. P. 165–169.
  25. 25. Yuldashev P.V., Karzova M.M., Kreider W., Rosnitskiy P.B., Sapozhnikov O.A., Khokhlova V.A. “HIFU beam”: a simulator for predicting axially symmetric nonlinear acoustic fields generated by focused transducers in a layered medium // IEEE Trans. Ultrason. Ferroelectr. Freq. Control. 2021. V. 68. № 9. P. 2837–2852.
  26. 26. Росницкий П.Б., Юлдашев П.В., Высоканов Б.А., Хохлова В.А. Граничное условие для расчета полей сильно фокусирующих излучателей на основе уравнения Хохлова–Заболотской // Акуст. журн. 2016. Т. 62. № 2. С. 153–162.
  27. 27. Ponomarchuk E.M., Yuldashev P.V., Nikolaev D.A., Tsysar S.A., Mironova A.A., Khokhlova V.A. Nonlinear ultrasound fields generated by an annular array with electronic and geometric adjustment of its focusing angle // Acoust. Phys. 2023. V. 69. № 4. P. 459–470.
  28. 28. Rosnitskiy P.B., Tsysar S.A., Karzova M.M., Buravkov S.V., Malkov P.G., Danilova N.V., Ponomarchuk E.M., Sapozhnikov O.A., Khokhlova T.D., Schade G.R., Maxwell A.D., Wang Y.N., Kadrev A.V., Chernyaev A.L., Okhobotov D.A., Kamalov A.A., Khokhlova V.A. Pilot ex vivo study on non-thermal ablation of human prostate adenocarcinoma tissue using boiling histotripsy // Ultrasonics. 2023. V. 133. 107029.
  29. 29. Khokhlova T., Rosnitskiy P., Hunter C., Maxwell A., Kreider W., ter Haar G., Costa M., Sapozhnikov O., Khokhlova V. Dependence of inertial cavitation induced by high intensity focused ultrasound on transducer F-number and nonlinear waveform distortion // J. Acoust. Soc. Am. 2018. V. 144. № 3. P. 1160–1169.
  30. 30. O’Neil H.T. Theory of focusing radiators // J. Acoust. Soc. Am. 1949. V. 21. № 5. P. 516–526.
  31. 31. Beissner K. Some basic relations for ultrasonic fields from circular transducers with a central hole // J. Acoust. Soc. Am. 2012. V. 131. № 1. P. 620–627.
  32. 32. Beissner K. On the lateral resolution of focused ultrasonic fields from spherically curved transducers // J. Acoust. Soc. Am. 2013. V. 134. № 5. P. 3943–3947.
  33. 33. Ultrasonics-Field Characterization-In Situ Exposure Estimation in Finite-Amplitude Ultrasonic Beams, document IEC/TS 61949. 2007.
  34. 34. Росницкий П.Б., Юлдашев П.В., Хохлова В.А. Влияние угловой апертуры медицинских ультразвуковых излучателей на параметры нелинейного ударно-волнового поля в фокусе // Акуст. журн. 2015. Т. 61. № 3. С. 325–332.
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