[1] S. Huard, Polarization of Light, J. Wiley and Sons, Ltd, New York (1997).
[2] D. Goldstein, Polarized Light, 2nd Edition, Marcel Dekker, Inc., New York (2003).
[3] M. H. Smith, P. Burke, A.Lompado,E. Tanner, L.W. Hillman, "Mueller matrix imaging polarimetry in dermatology," Proc. SPIE 3991, 210–216 (2000).
[4] M. H. Smith "Interpreting Mueller matrix images of tissues," Proc. SPIE 4257, 82–89 (2001).
[5] X. Wang, L. V. Wang "Propagation of polarized light in birefringent turbid media: A Monte Carlo study," J. Biomed. Opt. 7, 279–290 (2002).
[6] S. Lu, R. A. Chipman "Interpretation of Mueller matrices based on polar decomposition," J. Opt. Soc. Am. A 13, 1106–1113 (1996).
[7] A. Pierangelo, A. Nazac, A. Benali, P. Validire, H. Cohen, T. Novikova, B. H. Ibrahim, S. Manhas, C. Fallet, M.-R. Antonelli, A.-D. Martino, "Polarimetric imaging of uterine cervix: A case study," Opt. Express 21, 14120–14130 (2013).
[8] O. V. Angelsky, S. G. Hanson, A. P. Maksimyak, P. P. Maksimyak, "On the feasibility for determining the amplitude zeros in polychromatic fields," Optics Express 13, 4396–4405 (2005).
[9] A. G. Ushenko, V. P. Pishak, "Laser polarimetry of biological tissue: Principles and applications," Handbook of Coherent-Domain Optical Methods: Biomedical Diagnostics, Environmental and Material Science, V. Tuchin eds., Vol. 1, pp. 93–138, Kluwer Academic Publishers (2004).
[10] A. Y. Bekshaev, O. V. Angelsky, S. G. Hanson, C. Y. Zenkova, "Scattering of inhomogeneous circularly polarized optical field and mechanical manifestation of the internal energy flows," Phys. Rev. A 86, 023847 (2012).
[11] Y. A. Ushenko, T. M. Boychuk, V. T. Bachynsky, O. P. Mincer, "Diagnostics of structure and physiological state of birefringent biological tissues: Statistical, correlation and topological approaches," Handbook of Coherent-Domain Optical Methods, pp. 107–148. Springer Science+Business Media New York (2013), ISBN 978-1-4614-5175-4.
[12] Yu. A. Ushenko, G. B. Bodnar, G. D. Koval, "Classifying optical properties of surface-and bulkscattering biological layers with polarization singular states," J. Innov. Opt. Health Sci. 6, 1350018 (2013).
[13] Y. A. Ushenko, "Investigation of formation and interrelations of polarization singular structure and Mueller-matrix images of biological tissues and diagnostics of their cancer changes," J. Biomed. Opt. 16(6), 066006 (2011).
[14] Yu. A. Ushenko, "Statistical structure of polarization- inhomogeneous images of biotissues with different morphological structures," Ukr. J. Phys. Opt. 6, 63–70 (2005).
[15] Yu. A. Ushenko, A. P. Peresunko, Bozan Adel Baku, "A new method of Mueller-matrix diagnostics and differentiation of early oncological changes of the skin derma," Adv. Opt. Technol. 2010, Article ID 952423 (2010).
[16] Yu. A. Ushenko, O. I. Telenga, A. P. Peresunko, O. K. Numan, "New parameter for describing and analyzing the optical-anisotropic properties of biological tissues," J. Innov. Opt. Health Sci. 4, 463– 475 (2011).
[17] Yu. A. Ushenko, "The feasibilities of using the statistical, fractal and singular processing of hominal blood plasma phase images during the diagnostics and differentiation of mammary gland pathological states," J. Innov. Opt. Health Sci. 5, 1150001 (2012).
[18] S. Andersson-Engels, C. Klinteberg, K. Svanberg, S. Svanberg, "In vivo fluorescence imaging for tissue diagnostics," Phys. Med. Biol. 42, 815–824 (1997).
[19] R. R. Alfano, B. B. Das, J. Cleary, R. Prudente, E. J. Celmer, "Light sheds light on cancer — Distinguishing malignant tumors from benign tissues and tumors," Bull N Y Acad Med. 67, 143–150 (1991).
[20] M. Anidjar, D. Ettori, O. Cussenot, P. Meria, F. Desgrandchamps, A. Cortesse, P. Teillac, A. Le Duc, S. Avrillier, "Laser induced autofluorescence diagnosis of bladder tumors: Dependence on the excitation wavelength," J. Urol. 156, 1590–1596 (1996).
[21] A. G. Bohorfoush, "Tissue spectroscopy for gastrointestinal diseases," Endoscopy 28, 372–380 (1996).
[22] O. V. Angels kii, A.G. Ushenko, A. D. Archelyuk, S. B. Ermolenko, D. N.Burkovets "Structure ofmatrices for the transformation of laser radiation by biofractals," Quantum Electron. 29, 1074–1077 (1999).
[23] R. Alfano, D. Tata, J. Cordero et al., "Laser induced fluorescence spectroscopy from native cancerous and normal tissue," IEEE Quantum Electron. 20, 1507– 1511 (1984).
[24] O. V. Angelsky, A. Ya. Bekshaev, P. P. Maksimyak, A. P. Maksimyak, I. I. Mokhun, S. G. Hanson, C. Yu. Zenkova, A. V. Tyurin, "Circular motion of particles suspended in a Gaussian beam with circular polarization validates the spin part of the internal energy flow," Opt. Express 20, 11351–11356 (2012).
[25] J. Y. Qu, "Real time calibrated fluorescence imaging of tissue in vivo by using the combination of fluorescence and cross-polarized reflection," Biomedical Topical Meetings, Vol. 71 of OSA Trends in Optics and Photonics Series OSA, pp. 485–487, Washington, D.C. (2002).
[26] N. Ghosh, S. K. Majumder, P. K. Gupta, "Polarized fluorescence spectroscopy of human tissues," Opt. Lett. 27, 2007–2009 (2002).
[27] S. N. Savenkov, V. V. Marienko, E. A. Oberemok, O. I. Sydoruk, "Generalized matrix equivalence theorem for polarization theory," Phys. Rev. E. 74, 605–607 (2006).
[28] R. Stroka, R. Baumgartner, A. Buser, C. Ell, D. Jocham, E. Unsold, "Laser assisted detection of endogenous porphyrin in malignant diseases," SPIE Proc. 1641, 99–105 (1991).
[29] M.-A. D'Hallewin, A. R. Kamuhabwa, T. Roskams, P. A. M. De Witte, L. Baert, "Hypericin-based fluorescence diagnosis of bladder carcinoma," BJU Int. 89, 760–763 (2002).
[30] M. A. D'Hallewin, L. Bezdetnaya, F. Guillemin, "Fluorescence detection of bladder cancer: A review," Eur. Urol. 42, 417–425 (2002).