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Overview of skin diagnostic techniques based on multilayer skin models and spectrophotometrics

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Warianty tytułu
PL
Przegląd technik diagnostyki skóry w oparciu o modele wielowarstwowe skóry i spektrofotometrię
Języki publikacji
EN
Abstrakty
EN
Today, spectrophotometrics is a promising tool for non-invasive examination of the optical properties of human skin. The spectrum obtained during the study is carefully analysed by models developed by many scientists. Developed multilayer models are designed to reflect the most faithful processes occurring in the skin, its layers and essential elements. Many skin diseases are diagnosed: vitiligo, hemangios, skin birthmarks, melanoma. The article provides an overview of interesting solutions using spectrophotometrics in the process of diagnosing skin diseases.
PL
Obecnie spektrofotometria jest obiecującym narzędziem do nieinwazyjnego badania właściwości optycznych ludzkiej skóry. Otrzymane podczas badania widma poddawane są wnikliwej analizie dzięki opracowanym przez wielu naukowców modeli. Opracowane modele wielowarstwowe mają na celu oddać najwierniej procesy zachodzące w skórze, jej warstwy i istotne elementy. Diagnozowanych jest wiele chorób skóry: bielactwo, naczyniaki, znamiona skórne, czerniak. Artykuł przedstawia przegląd ciekawych rozwiązań z użyciem spektrofotometrii w procesie diagnostyki chorób skóry.
Rocznik
Strony
30--33
Opis fizyczny
Bibliogr. 40 poz., tab., wykr.
Twórcy
  • Lublin University of Technology, Department of Electronics and Information Technology, Lublin, Poland
Bibliografia
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  • [5] Cheong W. F., Prahl S. A., Welsh A. J.: A review of the optical properties of biological tissues. IEEE J. Quantum Electron. 26, 1990, 2166–2185.
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  • [9] Dwyer T., Blizzard L., Ashbolt R., Plumb J., Berwick M., Stankovich J. M.: Cutaneous melanin density measured by spectrophotometry and risk of malignant melanoma, basal cell carcinoma and inner arm melanin density and squamous cell carcinoma of the skin. Am. J. Epidemiol. 155, 2002, 614–621.
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  • [15] Harrison D. K.: The clinical application of optical spectroscopy in monitoring tissue oxygen supply following cancer treatment. In: Soh K. S., Kang K., Harrison D. (eds): The Primo Vascular System. Springer, New York, NY. [https://doi.org/10.1007/978-1-4614-0601-3_39].
  • [16] Jacques S. L., McAuliffe D. J.: The melanosome: Threshold temperature for explosive vaporization and internal absorption coefficient during pulsed laser irradiation. Photochem Photobiol 53, 1991, 769–775.
  • [17] Khan T. K., Wender P. A., Alkon D. L.: Bryostatin and its synthetic analog, picolog rescue dermal fibroblasts from prolonged stress and contribute to survival and rejuvenation of human skin equivalents. Journal of Cellular Physiology 233(2), 2018, 1523–1534.
  • [18] Lee J., Bangerter N., Cunningham C., DiCarlo J., Hu B., Nishimura D.: 3D high resolution skin imaging. Proceedings of the 12th Annual Meeting of ISMRM; Kyoto, Japan, 2004, 094.
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  • [20] Lisenko S., Kugeiko M.: A method for operative quantitative interpretation of multispectral images of biological tissues. Optics and Spectroscopy 115(4), 2013, 610–618.
  • [21] Lysenko S., Kugeiko M.: Method of noninvasive determination of optical and microphysical parameters of human skin. Measurement Techniques 56(1), 2013, 104–112.
  • [22] Maeda T., Arakawa N., Akahashi M., Aizu Y.: Monte Carlo Simulation of spectral reflectance using a multilayered skin tissue model. Optical Review 17(3), 2010, 223–229.
  • [23] Meyer L. E, Otberg N., Sterry W., Lademann J.: In vivo confocal scanning laser microscopy: comparison of the reflectance and fluorescence mode by imaging human skin. J. of Biomedical Optics 11(4), 2006, 044012.
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  • [28] Reuss J. L.: Multilayer modeling of reflectance pulse oximetry. IEEE Transactions on Biomedical Engineering 52(2), 2005.
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  • [30] Tuchin V. V., Yaroslavsky I. V.: Tissue optics, light distribution, and spectroscopy. Optical Engineering 33(10), 1994, 3180.
  • [31] Tuchin V. V.: Light scattering study of tissues. Physics-Uspekhi 40, 1997, 495–515.
  • [32] Tuchin V. V.: Tissue optics and photonics: Biological tissue structures. J. of Biomedical Photonics & Eng., 1(1), 2015.
  • [33] Valisuo P.: Photonics simulation and modelling of skin for design of spectrocutometer. Acta Wasaensia 242, Automation Technology 2, Universitas Wasaensis 2011
  • [34] Välisuo P., Mantere T., Alander J.: Solving optical skin simulation model parameters using genetic algorithm. 2nd International Conference on BioMedical Engineering and Informatics, 2009, 376–380.
  • [35] van der Mei A.F., Blizzard L., Stankovich J., Ponsonby A. L.: Misclassification due to body hair and seasonal variation on melanin density estimates for skin type using spectrophotometry. Journal of Photochemistry and Photobiology B: Biology 68, 2002, 45–52.
  • [36] van Gemert M. J. C., Jacques S. L., Sterenborg H. J. C. M., Star W. M.: Skin optics. IEEE Trans. Biomed. Eng. 36, 1989, 1146–1154.
  • [37] Vestergaard M. E., Macaskill P., Holt P. E., Menzies S. W.: Dermoscopy compared with naked eye examination for the diagnosis of primary melanoma: a meta-analysis of studies performed in a clinical setting. British Journal of Dermatology 159(3), 2008, 669–676.
  • [38] Wego A.: Accuracy simulation of an led based spectrophotometer. Optik, 124(7), 2013, 644–649.
  • [39] Wilson E. C. F., Emery J. D., Kinmonth A. L., Prevost A. T., Morris H. C., Humphrys E., Hall P. N., Burrows N., Bradshaw L., Walls J., Norris P., Johnson M., Walter F. M.: The cost-effectiveness of a novel SIAscopic diagnostic aid for the management of pigmented skin lesions in primary care. A Decision-Analytic Model, Value in Health 16(2), 2013, 356–366.
  • [40] Young A. R.: Chromophores in human skin. Physics in Medicine and Biology 42(5), 1997, 789–802.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-469a60d2-333d-4f56-9f55-af5903cc7246
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