Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Acoustic field characterization of the Duolith: measurements and modeling of a clinical shock wave therapy device.

Literature DB >> 23927207

Acoustic field characterization of the Duolith: measurements and modeling of a clinical shock wave therapy device.

Camilo Perez¹, Hong Chen, Thomas J Matula, Maria Karzova, Vera A Khokhlova.

Abstract

Extracorporeal shock wave therapy (ESWT) uses acoustic pulses to treat certain musculoskeletal disorders. In this paper the acoustic field of a clinical portable ESWT device (Duolith SD1) was characterized. Field mapping was performed in water for two different standoffs of the electromagnetic head (15 or 30 mm) using a fiber optic probe hydrophone. Peak positive pressures at the focus ranged from 2 to 45 MPa, while peak negative pressures ranged from -2 to -11 MPa. Pulse rise times ranged from 8 to 500 ns; shock formation did not occur for any machine settings. The maximum standard deviation in peak pressure at the focus was 1.2%, indicating that the Duolith SD1 generates stable pulses. The results compare qualitatively, but not quantitatively with manufacturer specifications. Simulations were carried out for the short standoff by matching a Khokhlov-Zabolotskaya-Kuznetzov equation to the measured field at a plane near the source, and then propagating the wave outward. The results of modeling agree well with experimental data. The model was used to analyze the spatial structure of the peak pressures. Predictions from the model suggest that a true shock wave could be obtained in water if the initial pressure output of the device were doubled.

Entities: Chemical Disease Gene

Mesh：

Year: 2013 PMID： 23927207 PMCID： PMC3745538 DOI： 10.1121/1.4812885

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

43 in total

1. Mechanical haemolysis in shock wave lithotripsy (SWL): I. Analysis of cell deformation due to SWL flow-fields.

Authors: M Lokhandwalla; B Sturtevant
Journal: Phys Med Biol Date: 2001-02 Impact factor: 3.609

2. High-energy extracorporeal shock wave treatment of nonunions.

Authors: J D Rompe; T Rosendahl; C Schöllner; C Theis
Journal: Clin Orthop Relat Res Date: 2001-06 Impact factor: 4.176

3. Effects of extracorporeal shockwave therapy on nanostructural and biomechanical responses in the collagenase-induced Achilles tendinitis animal model.

Authors: Seung Don Yoo; Samjin Choi; Gi-Ja Lee; Jinmann Chon; Yong Seol Jeong; Hun-Kuk Park; Hee-Sang Kim
Journal: Lasers Med Sci Date: 2012-01-25 Impact factor: 3.161

4. Comparison of the effectiveness of gene therapy with vascular endothelial growth factor or shock wave therapy to reduce ischaemic necrosis in an epigastric skin flap model in rats.

Authors: R Meirer; G M Huemer; M Oehlbauer; S Wanner; H Piza-Katzer; F S Kamelger
Journal: J Plast Reconstr Aesthet Surg Date: 2006-06-12 Impact factor: 2.740

5. Extracorporeal shockwaves versus surgery in the treatment of pseudoarthrosis of the carpal scaphoid.

Authors: A Notarnicola; L Moretti; S Tafuri; S Gigliotti; S Russo; L Musci; B Moretti
Journal: Ultrasound Med Biol Date: 2010-08 Impact factor: 2.998

Review 6. Extracorporeal shock wave therapy as a new and non-invasive angiogenic strategy.

Authors: Kenta Ito; Yoshihiro Fukumoto; Hiroaki Shimokawa
Journal: Tohoku J Exp Med Date: 2009-09 Impact factor: 1.848

7. Effects of shock wave therapy in the skin of patients with progressive systemic sclerosis: a pilot study.

Authors: Elisa Tinazzi; Ernesto Amelio; Elettra Marangoni; Claudio Guerra; Antonio Puccetti; Orazio Michele Codella; Sara Simeoni; Elisabetta Cavalieri; Martina Montagnana; Roberto Adani; Roberto Corrocher; Claudio Lunardi
Journal: Rheumatol Int Date: 2010-01-12 Impact factor: 2.631

8. Extracorporeal shock wave therapy for the treatment of chronic calcifying tendonitis of the rotator cuff: a randomized controlled trial.

Authors: Ludger Gerdesmeyer; Stefan Wagenpfeil; Michael Haake; Markus Maier; Markus Loew; Klaus Wörtler; Renee Lampe; Romain Seil; Gerhart Handle; Susanne Gassel; Jan D Rompe
Journal: JAMA Date: 2003-11-19 Impact factor: 56.272

Review 9. Extracorporeal shockwave therapy in musculoskeletal disorders.

Authors: Ching-Jen Wang
Journal: J Orthop Surg Res Date: 2012-03-20 Impact factor: 2.359

10. Extracorporeal shock-wave therapy in the treatment of pseudoarthrosis: a case report.

Authors: Stefan Endres; Markus Weiskirch; Christiane Hinz; Felix Hütter; Axel Wilke
Journal: Cases J Date: 2008-10-27

11 in total

1. Shock formation and nonlinear saturation effects in the ultrasound field of a diagnostic curvilinear probe.

Authors: Maria M Karzova; Petr V Yuldashev; Oleg A Sapozhnikov; Vera A Khokhlova; Bryan W Cunitz; Wayne Kreider; Michael R Bailey
Journal: J Acoust Soc Am Date: 2017-04 Impact factor: 1.840

2. Inactivation of Planktonic Escherichia coli by Focused 1-MHz Ultrasound Pulses with Shocks: Efficacy and Kinetics Upon Volume Scale-Up.

Authors: Andrew A Brayman; Brian E MacConaghy; Yak-Nam Wang; Keith T Chan; Wayne L Monsky; Valery P Chernikov; Sergey V Buravkov; Vera A Khokhlova; Thomas J Matula
Journal: Ultrasound Med Biol Date: 2018-06-23 Impact factor: 2.998

3. Nonlinear Effects in Ultrasound Fields of Diagnostic-type Transducers Used for Kidney Stone Propulsion: Characterization in Water.

Authors: M Karzova; B Cunitz; P Yuldashev; Y Andriyakhina; W Kreider; O Sapozhnikov; M Bailey; V Khokhlova
Journal: AIP Conf Proc Date: 2015-10-28

10. Focused electromagnetic high-energetic extracorporeal shockwave (ESWT) reduces pain levels in the nodular state of Dupuytren's disease-a randomized controlled trial (DupuyShock).

Authors: Karsten Knobloch; Marie Hellweg; Heiko Sorg; Tomas Nedelka
Journal: Lasers Med Sci Date: 2021-01-23 Impact factor: 3.161