[1. Xu, R., Xu, J., Qin, R., Huang, J. (2010) Developing multifunctional tissue simulating phantoms for quantitative biomedical optical imaging. Proc.SPIE, 7567, 75670K 10.1117/12.841162]Search in Google Scholar
[2. Fujimoto, J. G., & Farkas, G. L. (2009). Biomedical Optical Imaging. Quantitative Absorption and Scattering Spectra in Thick Tissues Using Broadband Diffuse Optical Spectroscopy, (12), 330-356. ]Search in Google Scholar
[3. Pogue, B. W., & Patterson, M. S. (2006). Review of tissue simulating phantoms for optical spectroscopy, imaging and dosimetry. Journal of Biomedical Optics, 11(4), 041102. 10.1117/1.233542916965130]Search in Google Scholar
[4. Ayers, F., Grant, A., Kuo, D., Cuccia, D. J., & Durkin, A. J. (2008). Fabrication and characterization of silicone-based tissue phantoms with tunable optical properties in the visible and near infrared domain. Proc. SPIE, 6870,687007. 10.1117/12.764969]Search in Google Scholar
[5. Di Ninni, P. Martelli, F., & Zaccanti, G. (2011). Toward a reference standard for tissue phantoms. Proc. SPIE, 7906, 79060M. 10.1117/12.874658]Search in Google Scholar
[6. Ankri, R., Fixler, D., & Taitelbaum, H. (2011). Reflected light intensity profile of twolayer tissues: phantom experiments. Proc. SPIE, 16, 085001. ]Search in Google Scholar
[7. Pravdin, A. B., Utz, S.U., & Kochubey, V.I. (1995). Physical modeling of human skin optical properties using milk and erythrocytes mixtures. Proc. SPIE, 2627, 221-226. 10.1117/12.228896]Search in Google Scholar
[8. Bergmanna, T., Beer, S., Maeder, U., Burg, J.M., Schlupp, P., Schmidts, T., Runkel, F., & Fiebich, M. (2011). Development of a skin phantom of the epidermis and evaluation by using fluorescence techniques. Proc. SPIE 7906E,18B. 10.1117/12.874676]Search in Google Scholar
[9. Saager, R.B., Kondru, C., Au, K., Sry, K., Ayers, F., & Durkin, A.J. (2010). Multilayer silicone phantoms for the evaluation of quantitative optical techniques in skin imaging. Proc. SPIE, 7567, 756706-1. 10.1117/12.842249]Search in Google Scholar
[10. Vo-Dinh, T. (2003). Biomedical Photonics Handbook. Photonics and Tissue Optics, (1). 10.1201/9780203008997]Search in Google Scholar
[11. Vo-Dinh, T. (2003). Biomedical Photonics Handbook. Optical Properties of Tissue, (2). 10.1201/9780203008997]Search in Google Scholar
[12. Sherwood, L. (2007). Human Physiology From Cells to Systems (6th ed-n). Digestive System, (16), 609. ]Search in Google Scholar
[13. Natural Phenomena Simulation Group, University of Waterloo: available at: [25.04.2013.] http://www.npsg.uwaterloo.ca/data/skin.php ]Search in Google Scholar
[14. Saknīte, I. (2012). Ādas hromoforu sadalījuma noteikšana ādā ar multispektrālo attēlošanu: maģistradarbs, LU Fizikas un matemātikas fakultāte (Latvia). ]Search in Google Scholar
[15. Sherwood, L. (2007). Human Physiology from Cells to Systems (6th ed-n). Body Defenses, (12), p.443. ]Search in Google Scholar
[16. Sherwood, L. (2007). Human Physiology from Cells to Systems (6th ed-n). The Blood, (11), p. 387. ]Search in Google Scholar
[17. Demos, S.G., & Alfano, R.R. (1997). Optical polarization imaging. Applied Optics, 36 (1), 150 - 155. 10.1364/AO.36.00015018250656]Search in Google Scholar
[18. VariSpec Brochure. Research and Instrumentation, Inc., available at: [18.02.2010.]. http://www.cri-inc.com/support/components.asp. ]Search in Google Scholar
[19. Natural Phenomena Simulation Group, University of Waterloo, available at: [25.04.2013.] http://www.npsg.uwaterloo.ca/data/skin.php ]Search in Google Scholar
[20. Negri, S., Federici, G., Farinato, S., Fila, C. (2009). Human plasma as dermal scaffold for the generation of a completely autologous bioengineered skin. Journal of Clinical Rehabilitative Tissue Engineering Research, 13 ]Search in Google Scholar