Top

Published in:

01-01-2012 | Original Article

Experimental verification and validation of a computer model for light–tissue interaction

Authors: Aletta Elizabeth Karsten, Ann Singh, Max W. Braun

Published in: Lasers in Medical Science | Issue 1/2012

Abstract

Laser light is frequently used in both diagnostics and treatment of patients. For any laser treatment to be effective it is important to deliver the correct dose at the treatment site. Human skin scatters and absorbs laser light in the visible wavelength region, which results in a decrease in fluence some distance into the skin. Computer simulations can be used to predict the fluence at the treatment site. Liquid and solid phantoms were prepared and the optical properties were measured. These values were then used as input values to a commercial software package simulating the different layers of skin representing phantoms. The transmission and reflected fractions of the different phantoms were measured with an integrating sphere and compared with the computer simulations. The results showed very good agreement with the measured values and the model can therefore be used with confidence to predict fluence at any treatment site inside the skin.

Tuchin V (2000) Tissue optics: light scattering methods and instruments for medical diagnostics. SPIE Press, pp 3–108

Drakaki E, Psycharakis S, Makropoulou M, Serafetinides AA (2005) Optical properties and chromophore concentration measurements in tissue-like phantoms. Opt Commun 254:40–51CrossRef

Jacques SL (2010) How tissue optics affect dosimetry of photodynamic therapy. J Biomed Opt. doi:10.1117/1.3494561

Star WM, Marijnissen JPA, van Gemert MJC (1988) Light dosimetry in optical phantoms and in tissues: I. Multiple flux and transport theory. Phys Med Biol 3(4):437–454CrossRef

Grossweiner LI (1997) PDT light dosimetry revisited. J Photochem Photobiol, B 38:258–268CrossRef

Agache P, Humbert P (2004) Measuring the skin. Springer, Berlin Heidelberg New York, ISBN 3-540-01771-2, pp 473–474

Henyey L, Greenstein J (1994) Diffuse radiation in the galaxy. Astrophys J 93:70–83CrossRef

Star WM (1997) Light dosimetry in vivo. Phys Med Biol 42:763–787PubMedCrossRef

Flock S, Jaques S, Wilson B (1992) Optical properties of intralipid A phantom medium for light propagation study. Lasers Med Surg 2:510–519CrossRef

10.

Michielsen K, De Raedt H, Przeslawski J, Garcia N (1998) Computer simulation of time-resolved optical imaging of objects hidden in turbid media. Phys Rep 304:89–144CrossRef

11.

van Staveren HJ, Moes CJM, van Marie J, Prahl SA, van Gemert MJC (1991) Light scattering in Intralipid-10% in the wavelength range of 400–1,100 nm. Appl Opt 30(31):4507–4514PubMedCrossRef

12.

Choukeife JE, L’Huillier JP (1999) Measurements of scattering effects within tissue-like media at two wavelengths of 632.8 nm and 680 nm. Lasers Med Sci 14:286–296CrossRef

13.

Firbank M, Delpy DT (1993) A design for a stable and reproducible phantom for use in near infra-red imaging and spectroscopy. Phys Med Biol 38:847–853CrossRef

14.

Singh A, Karsten AE, Mputle I, Chetty A, Naidoo K (2009) Determination of the optical properties of PNIPAAm gels used in biological applications. Proc SPIE 7373:737317. doi:10.1117/12.831882 CrossRef

15.

Das BB, Liu F, Alfano RR (1997) Time-resolved fluorescence and photon migration studies in biomedical and model random media. Rep Prog Phys 60:227–292CrossRef

16.

Dimofte A, Finlay JC, Zhu TC (2005) A method for determination of the absorption and scattering properties interstitially in turbid media. Phys Med Biol 50:2291–2311PubMedCrossRef

17.

Dam JS, Dalgaard P, Fabricius PE, Andersson-Engels S (2000) Multiple polynomial regression method for determination of biomedical optical properties from integrating sphere measurements. Appl Opt 39:1202–1209PubMedCrossRef

18.

Singh A, Karsten AE, Dam, JS (2008) Robustness and accuracy of the calibration model for the determination of the optical properties of chicken skin. Proceedings of the International Conference of the World Association of Laser Therapy, Sun City, South Africa, pp 165–169, (CD ISBN 978-88-7587-471-1)]

19.

Jacques SL (2008) Modeling tissue optics using Monte Carlo modeling: a tutorial. Optical Interactions with Tissue and Cells XIX, edited by Steven L. Jacques, William P. Roach, Robert J. Thomas, Proc. of SPIE Vol. 6854, 68540T. 1605-7422/08/$18 · doi: 10.1117/12.776997 Proc. of SPIE Vol. 6854 68540T-1

20.

http://omlc.ogi.edu/software/mc/

21.

ASAP Technical guide Radiometric analysis http://www.breault.com/resources/kbasePDF/brotg0909_radiometry.pdf

22.

Prahl SA, Keijzer M, Jacques SL, Welch AJ (1989) A Monte Carlo model of light propagation in tissue. SPIE Institute Series, vol. IS 5, pp 102–111

Title: Experimental verification and validation of a computer model for light–tissue interaction
Authors: Aletta Elizabeth Karsten
Ann Singh
Max W. Braun
Publication date: 01-01-2012
Publisher: Springer-Verlag
Published in: Lasers in Medical Science / Issue 1/2012
Print ISSN: 0268-8921
Electronic ISSN: 1435-604X
DOI: https://doi.org/10.1007/s10103-011-0926-x

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Experimental verification and validation of a computer model for light–tissue interaction

Abstract

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 1/2012

Effects of 940 nm light-emitting diode (led) on sciatic nerve regeneration in rats

Different CO2 laser vaporization protocols for the therapy of oral precancerous lesions and precancerous conditions: a 10-year follow-up

Microtensile bond strength of an etch-and-rinse adhesive to enamel and dentin after Er:YAG laser pretreatment with different pulse durations

Ti:sapphire femtosecond laser ablation of dental enamel, dentine, and cementum

Low-level infrared laser effect on plasmid DNA

An experimental study of low-level laser therapy in rat Achilles tendon injury