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[4] [4] O. V. Angelsky, A. G. Ushenko, Yu. A. Ushenko, V. P. Pishak, "Statistical and fractal structure of biological tissue Mueller matrix images," in Optical Correlation Techniques and Applications, O. V. Angelsky, Ed., Society of Photo-Optical InstrumentationEngineers,Washington, pp. 213-266 (2007).

[5] [5] O. V. Angelsky, A. G. Ushenko, Yu. A. Ushenko, V. P. Pishak, A. P. Peresunko, "Statistical, correlation, and topological approaches in diagnostics of the structure and physiological state of birefringent biological tissues," in Handbook of Photonics for Biomedical Science, V. V. Tuchin, Ed., CRC Press, USA, pp. 21-67 (2010).

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[10] [10] A. G. Ushenko, D. N. Burkovets, Yu. A. Ushenko, "Polarization-phase mapping and reconstruction of biological tissue architectonics during diagnosis of pathological lesions," Opt. Spectrosc. 93, 449-456 (2002).

[11] [11] A. G. Ushenko, "Stokes correlometry of biotissues," Laser Phys. 10, 1286-1292 (2000).

[12] [12] A. G. Ushenko, "The vector structure of laser biospeckle fields and polarization diagnostics of collagen skin structures," Laser Phys. 10, 1143-1149 (2000).

[13] [13] A. G. Ushenko, "Laser polarimetry of polarizationphase statistical moments of the object field of optically anisotropic scattering layers," Opt. Spectrosc. 91, 313-316 (2001).

[14] [14] A. G. Ushenko, "Polarization contrast enhancement of images of biological tissues under the conditions of multiple scattering," Opt. Spectrosc. 91, 937-940 (2001).

[15] [15] A. G. Ushenko, "Laser probing of biological tissues and the polarization selection of their images," Opt. Spectrosc. 91, 932-936 (2001).

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[17] [17] A. G. Ushenko, "Polarization correlometry of angular structure in the micro-relief pattern or rough surfaces," Opt. Spectrosc. 92, 227-229 (2002).

[18] [18] O. V. Angelsky, A. G. Ushenko, Ye. G. Ushenko, "2D Stokes polarimetry of biospeckle tissues images in pre-clinic diagnostics of their pre-cancer states," J. Holography Speckle 2, 26-33 (2005).

[19] [19] O. V. Angelsky, A. G. Ushenko, Ye. G. Ushenko, "Complex degree of mutual polarization of biological tissue coherent images for the diagnostics of their physiological state," J. Biomed. Opt. 10, 060502 (2005).

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[21] [21] O. V. Angelsky, A. G. Ushenko, Ye. G. Ushenko, Y. Y. Tomka, "Polarization singularities of biological tissues images," J. Biomed. Opt. 11, 054030 (2006).

[22] [22] O. G. Ushenko, S. G. Guminetsky, A. V. Motrich, "Optical properties of urine, blood plasma and pulmonary condensate of the patients with pulmonary form of tuberculosis," Photoelectron. 16, 133-139 (2007).

[23] [23] S. H. Guminetskiy, O. G. Ushenko, I. P. Polyanskiy, A. V. Motrych, F. V. Grynchuk, "The optical method for investigation of the peritonitis progressing process," Proc. SPIE 7008, 700827 (2008).

[24] [24] A. Ushenko, S. Yermolenko, A. Prydij, S. Guminetsky, I. Gruia, O. Toma, K. Vladychenko, "Statistical and fractal approaches in laser polarimetry diagnostics of the cancer prostate tissues," Proc. SPIE 7008, 70082C (2008).

[25] [25] A. G. Ushenko, A. I. Fediv, Yu. F. Marchuk, "Correlation and fractal structure of Jones matrices of human bile secret," Proc. SPIE 7368, 73681Q (2009).

[26] [26] A. G. Ushenko, Y. Y. Tomka, V. I. Istratiy, "Polarization selection of two-dimensional phaseinhomogeneous birefringence images of biotissues," Proc. SPIE 7388, 73881L (2009).

[27] [27] A. G. Ushenko, A. I. Fediv, Yu. F. Marchuk, "Singular structure of polarization images of bile secret in diagnostics of human physiological state," Proc. SPIE 7368, 73681S (2009).

[28] [28] S. B. Yermolenko, A. G. Ushenko, P. Ivashko, "Spectropolarimetry of cancer change of biotissues," Proc. SPIE 7388, 73881D (2009).

[29] [29] A. G. Ushenko, I. Z. Misevich, V. Istratiy, I. Bachyns'ka, A. P. Peresunko, O. K. Numan, T. G. Moiysuk, "Evolution of statistic moments of 2D-distributions of biological liquid crystal net Mueller matrix elements in the process of their birefringent structure changes," Adv. Opt. Technol. 2010, 423145 (2010).

[30] [30] O. V. Dubolazov, A. G. Ushenko, V. T. Bachynsky, A. P. Peresunko, O. Ya. Vanchulyak, "On the feasibilities of using the wavelet analysis of Mueller matrix images of biological crystals," Adv. Opt. Technol. 2010, 162832 (2010).