Modeling and measurements of light transmission through human tissues

• Autorzy: Krawiecki, Z. , Cysewska-Sobusiuk,A. , Wiczyński, G. , Odon, A.
• Języki publikacji: EN

Abstrakty

EN

The paper presents selected results of studies connected with modeling of a biological object which could be used for simulation and measurements of the selected human tissues optical transmittance. The studies were performed for transilluminated homogeneous tissue layers as well as for objects consisted of different tissues. During simulations the software built with LabVIEW environment was used. Experimental verification of the model structure was made with spectrophotometry. The presented examples of modeling concern the transmittance spectra for two selected specific objects: the venous blood and muscle tissue analyzed in the wavelength range extending from 360 nm to 900 nm. The implemented model could be used in estimating the content and thickness of particular layers distinguished in a complex object and prediction of their transillumination efficiency.

Słowa kluczowe

EN

biooptics; transillumination; light-tissue interaction; spectrophotometric measurements

• Czasopismo: Bulletin of the Polish Academy of Sciences. Technical Sciences
• Rocznik: 2008
• Tom: Vol. 56, nr 2
• Strony: 147-154
• Opis fizyczny: Bibliogr. 22 poz., rys.

Twórcy

autor

Krawiecki, Z.

autor

Cysewska-Sobusiuk,A.

autor

Wiczyński, G.

autor

Odon, A.

• Institute of Electrical Engineering and Electronics. Division of Metrology and Optoelectronics, Poznan University of Technology, 3A Piotrowo St., 60-965 Poznan, Poland,

Bibliografia

• [1] R.S. Jones, G.D. Huynh, G.C. Jones, and D. Fried, “Near-infrared transillumination at 1310 nm for the imaging of early dental decay”, Optics Express 11, 2259–2265 (2003).
• [2] S.M. Hanspaul and I.J. Frieden, “Transillumination of a cystic lymphatic malformation”, New England J. Medicine 349, 18 (2003).
• [3] Ch. Eaton, “Clinical example flashlight transillumination for tumor diagnosis”, in: The Electronic Textbook of Hand Surgery, www.eaton.hand.com (2005).
• [4] A. Cysewska-Sobusiak and G. Wiczynski, “Examples of transillumination techniques used in medical measurements and imaging”, Lecture Notes in Control and Information Sciences 335, 351–364 (2006).
• [5] J. Bauer, E. Boerner, H. Podbielska, and A. Suchwalko, “Pattern recognition methods of transillumination images for diagnosis of rheumatoid arthritis”, Proc. SPIE 5959, 15-20 (2005).
• [6] A. Cysewska-Sobusiak and Z. Krawiecki, “Influence of changes in optical pathway on efficiency of light transmission through tissues”, Proc. SPIE 5064, 295–302 (2003).
• [7] J.G. Webster, Design of Pulse Oximetry, IOP Publishing Ltd, London, 1997.
• [8] J. Moyle, Pulse Oximetry, 2nd ed., BMJ books, London, 2002.
• [9] J.C. Hebden, D.A. Boas, J.S. George, and A.J. Durkin, “Topics in biomedical optics: introduction”, Applied Optics 42, 2869–2870 (2003).
• [10] A. Cysewska-Sobusiak, “Powers and limitations of noninvasive measurements implemented in pulse oximetry”, Biocybernetics and Biomedical Engineering 22, 79–96 (2002).
• [11] W.F. Cheong, S.A. Prahl, and A.J. Welch, “A review of the optical properties of biological tissues”, IEEE J. Q. Electron. 26, 2166–2185 (1990).
• [12] V.V. Tuchin, ”Light interaction with biological tissues (overview)”, Proc. SPIE 1884, 234–272 (1993).
• [13] F.A. Duck, Physical Properties of Tissue: A Comprehensive Reference Book, Academia Press, San Diego, 1990.
• [14] V.V. Tuchin, Tissue Optics: Light Scattering Methods and Instruments for Medical Diagnosis, vol. TT38, SPIE Press, Bellingham, 2000.
• [15] R. Graaf, J.G. Aarnoudse, F.F. de Mul, and M.W. Jentik, “Similarity relations for anisotropic scattering in absorbing media”, Optical Engineering 32, 244–252 (1993).
• [16] R. Srinivasan, D. Kumar, and S. Megha, “Optical tissue-equivalent phantoms for medical imaging”, Trends in Biomaterials & Artificial Organs 15, 42–47 (2002).
• [17] E.J. Van Kampen and W.G. Zijlstra, “Spectrophotometry of hemoglobin and hemoglobin derivatives”, Adv. Clin. Chem. 23, 199–257 (1983).
• [18] A. Cysewska-Sobusiak, ”One-dimensional representation of light-tissue interaction for application in noninvasive oximetry”, Optical Engineering 36, 1225–1233 (1997).
• [19] A. Cysewska-Sobusiak, “Modeling and simulation of a tissue response to light transmission”, Med.&Biol.Eng.&Comput. 37 (Suppl. 1), 216–217 (1999).
• [20] Varian UV-VIS-NIR Spectrophotometers, http://www.varianinc.com.
• [21] G.W. Johnson, LabView Power Programming, McGraw-Hill, New Zealand, 1998.
• [22] E. Rosow and J.B. Olansen, Virtual Bio-Instrumentation: Biomedical, Clinical and Healthcare Applications in LabVIEW, Prentice Hall, New Jersey, 2001.