Effect of young's modulus on bubble formation and pressure waves during pulsed holmium ablation of tissue phantoms

E. Duco Jansen, Thomas Asshauer, Martin Frenz, Guy Delacretaz, Massoud Motamedi, A. J. Welch

Research output: Contribution to journalConference article

1 Citation (Scopus)

Abstract

Mechanical injury during pulsed laser ablation of tissue is caused by rapid bubble expansions and collapse or by laserinduced pressure waves. In this study the effect of material elasticity on the ablation process has been investigated. Polyacrylamide tissue phantoms with various water concentrations (75 -95%) were made. The Young's moduli of the gels were determined by measuring the stress-strain relationship. An optical fiber (200 or 400 μm) was translated into the clear gel and one pulse of holmium:YAG laser radiation was given. The laser was operated in either the Q-switched mode (τp =500 ns, Qp = 14 ± mJ, 200 μm fiber, H0 =446 mJ/mm2) or the free-running mode (τp = 100 μs, Qp = 200 ± 5 mJ, 400 μm fiber, H0 = 1592 mJ:mn2) Bubble formation inside the gels was recorded using a fast flash photography setup while simultaneously recording pressures with a PVDP needle hydrophone (40 ns risetime) positioned in the gel, approximately 2 mm away from the fibertip. A thermo-elastic expansion wave was measured only during Q-switched pulse delivery. The amplitude of this wave (-40 bar at 1 mm from the fiber) did not vary significantly in any of the phantoms investigated. Rapid bubble formation and collapse was observed inside the clear gels. Upon bubble collapse, a pressure transient was emitted; the amplitude of this transient depended strongly on bubble size and geometry. It was found that 1) the bubble was almost spherical for the Q-switched pulse and became more elongated for the free-running pulse, and 2) the maximum bubble size and thus the collapse amplitude decreased with an increase in Young's modulus (from 68 ± 11 bar at 1 mm in 95% water gel to 25 ± 10 bar at 1 mm in 75% water gel).

Original languageEnglish (US)
Pages (from-to)386-392
Number of pages7
JournalProceedings of SPIE - The International Society for Optical Engineering
Volume2391
DOIs
StatePublished - May 22 1995
EventLaser-Tissue Interaction VI 1995 - San Jose, United States
Duration: Feb 1 1995Feb 8 1995

Fingerprint

Holmium
Bubble formation
holmium
Ablation
Young's Modulus
Phantom
elastic waves
Bubble
ablation
modulus of elasticity
bubbles
Gels
Elastic moduli
gels
Tissue
Fiber
pulses
Water
fibers
Fibers

Keywords

  • Ablation
  • Bubble formation
  • Holmium laser
  • Infrared
  • Pressure
  • Pulsed laser
  • Young's modulus

ASJC Scopus subject areas

  • Electronic, Optical and Magnetic Materials
  • Condensed Matter Physics
  • Computer Science Applications
  • Applied Mathematics
  • Electrical and Electronic Engineering

Cite this

Effect of young's modulus on bubble formation and pressure waves during pulsed holmium ablation of tissue phantoms. / Jansen, E. Duco; Asshauer, Thomas; Frenz, Martin; Delacretaz, Guy; Motamedi, Massoud; Welch, A. J.

In: Proceedings of SPIE - The International Society for Optical Engineering, Vol. 2391, 22.05.1995, p. 386-392.

Research output: Contribution to journalConference article

@article{b9074a3c44224f0cb597cd9ef696f5f7,
title = "Effect of young's modulus on bubble formation and pressure waves during pulsed holmium ablation of tissue phantoms",
abstract = "Mechanical injury during pulsed laser ablation of tissue is caused by rapid bubble expansions and collapse or by laserinduced pressure waves. In this study the effect of material elasticity on the ablation process has been investigated. Polyacrylamide tissue phantoms with various water concentrations (75 -95{\%}) were made. The Young's moduli of the gels were determined by measuring the stress-strain relationship. An optical fiber (200 or 400 μm) was translated into the clear gel and one pulse of holmium:YAG laser radiation was given. The laser was operated in either the Q-switched mode (τp =500 ns, Qp = 14 ± mJ, 200 μm fiber, H0 =446 mJ/mm2) or the free-running mode (τp = 100 μs, Qp = 200 ± 5 mJ, 400 μm fiber, H0 = 1592 mJ:mn2) Bubble formation inside the gels was recorded using a fast flash photography setup while simultaneously recording pressures with a PVDP needle hydrophone (40 ns risetime) positioned in the gel, approximately 2 mm away from the fibertip. A thermo-elastic expansion wave was measured only during Q-switched pulse delivery. The amplitude of this wave (-40 bar at 1 mm from the fiber) did not vary significantly in any of the phantoms investigated. Rapid bubble formation and collapse was observed inside the clear gels. Upon bubble collapse, a pressure transient was emitted; the amplitude of this transient depended strongly on bubble size and geometry. It was found that 1) the bubble was almost spherical for the Q-switched pulse and became more elongated for the free-running pulse, and 2) the maximum bubble size and thus the collapse amplitude decreased with an increase in Young's modulus (from 68 ± 11 bar at 1 mm in 95{\%} water gel to 25 ± 10 bar at 1 mm in 75{\%} water gel).",
keywords = "Ablation, Bubble formation, Holmium laser, Infrared, Pressure, Pulsed laser, Young's modulus",
author = "Jansen, {E. Duco} and Thomas Asshauer and Martin Frenz and Guy Delacretaz and Massoud Motamedi and Welch, {A. J.}",
year = "1995",
month = "5",
day = "22",
doi = "10.1117/12.209906",
language = "English (US)",
volume = "2391",
pages = "386--392",
journal = "Proceedings of SPIE - The International Society for Optical Engineering",
issn = "0277-786X",
publisher = "SPIE",

}

TY - JOUR

T1 - Effect of young's modulus on bubble formation and pressure waves during pulsed holmium ablation of tissue phantoms

AU - Jansen, E. Duco

AU - Asshauer, Thomas

AU - Frenz, Martin

AU - Delacretaz, Guy

AU - Motamedi, Massoud

AU - Welch, A. J.

PY - 1995/5/22

Y1 - 1995/5/22

N2 - Mechanical injury during pulsed laser ablation of tissue is caused by rapid bubble expansions and collapse or by laserinduced pressure waves. In this study the effect of material elasticity on the ablation process has been investigated. Polyacrylamide tissue phantoms with various water concentrations (75 -95%) were made. The Young's moduli of the gels were determined by measuring the stress-strain relationship. An optical fiber (200 or 400 μm) was translated into the clear gel and one pulse of holmium:YAG laser radiation was given. The laser was operated in either the Q-switched mode (τp =500 ns, Qp = 14 ± mJ, 200 μm fiber, H0 =446 mJ/mm2) or the free-running mode (τp = 100 μs, Qp = 200 ± 5 mJ, 400 μm fiber, H0 = 1592 mJ:mn2) Bubble formation inside the gels was recorded using a fast flash photography setup while simultaneously recording pressures with a PVDP needle hydrophone (40 ns risetime) positioned in the gel, approximately 2 mm away from the fibertip. A thermo-elastic expansion wave was measured only during Q-switched pulse delivery. The amplitude of this wave (-40 bar at 1 mm from the fiber) did not vary significantly in any of the phantoms investigated. Rapid bubble formation and collapse was observed inside the clear gels. Upon bubble collapse, a pressure transient was emitted; the amplitude of this transient depended strongly on bubble size and geometry. It was found that 1) the bubble was almost spherical for the Q-switched pulse and became more elongated for the free-running pulse, and 2) the maximum bubble size and thus the collapse amplitude decreased with an increase in Young's modulus (from 68 ± 11 bar at 1 mm in 95% water gel to 25 ± 10 bar at 1 mm in 75% water gel).

AB - Mechanical injury during pulsed laser ablation of tissue is caused by rapid bubble expansions and collapse or by laserinduced pressure waves. In this study the effect of material elasticity on the ablation process has been investigated. Polyacrylamide tissue phantoms with various water concentrations (75 -95%) were made. The Young's moduli of the gels were determined by measuring the stress-strain relationship. An optical fiber (200 or 400 μm) was translated into the clear gel and one pulse of holmium:YAG laser radiation was given. The laser was operated in either the Q-switched mode (τp =500 ns, Qp = 14 ± mJ, 200 μm fiber, H0 =446 mJ/mm2) or the free-running mode (τp = 100 μs, Qp = 200 ± 5 mJ, 400 μm fiber, H0 = 1592 mJ:mn2) Bubble formation inside the gels was recorded using a fast flash photography setup while simultaneously recording pressures with a PVDP needle hydrophone (40 ns risetime) positioned in the gel, approximately 2 mm away from the fibertip. A thermo-elastic expansion wave was measured only during Q-switched pulse delivery. The amplitude of this wave (-40 bar at 1 mm from the fiber) did not vary significantly in any of the phantoms investigated. Rapid bubble formation and collapse was observed inside the clear gels. Upon bubble collapse, a pressure transient was emitted; the amplitude of this transient depended strongly on bubble size and geometry. It was found that 1) the bubble was almost spherical for the Q-switched pulse and became more elongated for the free-running pulse, and 2) the maximum bubble size and thus the collapse amplitude decreased with an increase in Young's modulus (from 68 ± 11 bar at 1 mm in 95% water gel to 25 ± 10 bar at 1 mm in 75% water gel).

KW - Ablation

KW - Bubble formation

KW - Holmium laser

KW - Infrared

KW - Pressure

KW - Pulsed laser

KW - Young's modulus

UR - http://www.scopus.com/inward/record.url?scp=0008531754&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=0008531754&partnerID=8YFLogxK

U2 - 10.1117/12.209906

DO - 10.1117/12.209906

M3 - Conference article

AN - SCOPUS:0008531754

VL - 2391

SP - 386

EP - 392

JO - Proceedings of SPIE - The International Society for Optical Engineering

JF - Proceedings of SPIE - The International Society for Optical Engineering

SN - 0277-786X

ER -