Proceedings Paper
Optical and thermal simulations of noninvasive laser coagulation of the human vas deferens| Format | Member Price | Non-Member Price |
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Paper Abstract
Successful noninvasive laser coagulation of the canine vas deferens, in vivo, has been previously reported.
However, there is a significant difference between the optical properties of canine and human skin. In this study,
Monte Carlo simulations of light transport through tissue and heat transfer simulations are performed to determine
the feasibility of noninvasive laser vasectomy in humans. A laser wavelength of 1064 nm was chosen for deep
optical penetration in tissue. Monte Carlo simulations determined the spatial distribution of absorbed photons inside
the tissue layers (epidermis, dermis, and vas). The results were convolved with a 3-mm-diameter laser beam, and
then used as the spatial heat source for the heat transfer model. A laser pulse duration of 500 ms and pulse rate of 1
Hz, and cryogen spray cooling were incident on the tissue for 60 s. Average laser power (5-9 W), cryogen pulse
duration (60-100 ms), cryogen cooling rate (0.5-1.0 Hz), and increase in optical transmission due to optical clearing
(0-50 %), were studied. After application of an optical clearing agent to increase skin transmission by 50%, an
average laser power of 6 W, cryogen pulse duration of 60 ms, and cryogen cooling rate of 1 Hz resulted in vas
temperatures of ~ 60°C, sufficient for thermal coagulation, while 1 mm of the skin surface (epidermis and dermis)
remained at a safe temperature of ~ 45 °C. Monte Carlo and heat transfer simulations indicate that it is possible to
noninvasively thermally coagulate the human vas without adverse effects (e.g. scrotal skin burns), if an optical
clearing agent is applied to the skin prior to the procedure.
Paper Details
Date Published: 17 February 2011
PDF: 8 pages
Proc. SPIE 7883, Photonic Therapeutics and Diagnostics VII, 78831C (17 February 2011); doi: 10.1117/12.873175
Published in SPIE Proceedings Vol. 7883:
Photonic Therapeutics and Diagnostics VII
Kenton W. Gregory M.D.; Nikiforos Kollias; Andreas Mandelis; Henry Hirschberg M.D.; Hyun Wook Kang; Anita Mahadevan-Jansen; Brian Jet-Fei Wong M.D.; Justus F. R. Ilgner M.D.; Bodo E. Knudsen M.D.; E. Duco Jansen; Steen J. Madsen; Guillermo J. Tearney; Bernard Choi; Haishan Zeng; Laura Marcu, Editor(s)
PDF: 8 pages
Proc. SPIE 7883, Photonic Therapeutics and Diagnostics VII, 78831C (17 February 2011); doi: 10.1117/12.873175
Show Author Affiliations
Gino R. Schweinsberger, The Univ. of North Carolina at Charlotte (United States)
Christopher M. Cilip, The Univ. of North Carolina at Charlotte (United States)
Susan R. Trammell, The Univ. of North Carolina at Charlotte (United States)
Christopher M. Cilip, The Univ. of North Carolina at Charlotte (United States)
Susan R. Trammell, The Univ. of North Carolina at Charlotte (United States)
Harish Cherukuri, The Univ. of North Carolina at Charlotte (United States)
Nathaniel M. Fried, The Univ. of North Carolina at Charlotte (United States)
Johns Hopkins Medical Institutions (United States)
Nathaniel M. Fried, The Univ. of North Carolina at Charlotte (United States)
Johns Hopkins Medical Institutions (United States)
Published in SPIE Proceedings Vol. 7883:
Photonic Therapeutics and Diagnostics VII
Kenton W. Gregory M.D.; Nikiforos Kollias; Andreas Mandelis; Henry Hirschberg M.D.; Hyun Wook Kang; Anita Mahadevan-Jansen; Brian Jet-Fei Wong M.D.; Justus F. R. Ilgner M.D.; Bodo E. Knudsen M.D.; E. Duco Jansen; Steen J. Madsen; Guillermo J. Tearney; Bernard Choi; Haishan Zeng; Laura Marcu, Editor(s)
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