Methods and means of asymutal-invariant muller matrix polyarimetry of optical and anisotropic biological layers
Abstract
Objectives: The work is aimed at the theoretical substantiation and experimental development of the azimuthally invariant polarimetry method of partially depolarizing optical anisotropic biological layers on the basis of coordinate Muller-matrix mapping of histological sections for differential diagnostics of changes in optical anisotropy, which are associated with the emergence of pathological states.
Results: The method of azimuthally invariant Muller-matrix mapping of optically anisotropic samples of the myocardium is proposed and grounded. The values of azimuthally invariant matrix element, superposition of matrix elements and the magnitude of the matrix vector distributions are obtained.
Conclusion: The magnitude of the 1st-4th order statistical moments’ dependences, which characterize the distribution of the Muller-matrix invariant (MMI) of the histological sections of the myocardium are determined. The study of the possibility of differentiating causes of death due to ischemic heart disease (IHD) and acute coronary insufficiency (ACI) conducted from the standpoint of evidence-based medicine.
Downloads
References
Tuchin, V. V., & Tuchin, V. (2007). Tissue optics: light scattering methods and instruments for medical diagnosis.
Wang, X., Yao, G., & Wang, L. V. (2002). Monte Carlo model and single-scattering approximation of the propagation of polarized light in turbid media containing glucose. Applied optics, 41(4), 792-801.
Wang, X., & Wang, L. V. (2002). Propagation of polarized light in birefringent turbid media: a Monte Carlo study. Journal of Biomedical Optics, 7(3), 279-291.
Ghosh, N., & Vitkin, A. I. (2011). Tissue polarimetry: concepts, challenges, applications, and outlook. Journal of biomedical optics, 16(11), 110801.
Ghosh, N., Wood, M., & Vitkin, A. (2010). Polarized Light Assessment of Complex Turbid Media Such as Biological Tissues Us-ing Mueller Matrix Decomposition. In Handbook of photonics for biomedical science (pp. 253–282). CRC Press.
Tynes, H. H., Kattawar, G. W., Zege, E. P., Katsev, I. L., Prikhach, A. S., & Chaikovskaya, L. I. (2001). Monte Carlo and multicomponent approximation methods for vector radiative transfer by use of effective Mueller matrix calculations. Applied Optics, 40(3), 400-412.
Khlebtsov, N. G., Maksimova, I. L., Meglinski, I., Wang, L. V., & Tuchin, V. V. (2016). Introduction to light scattering by biological objects.
Ushenko, A. G., & Pishak, V. P. (2004). Laser polarimetry of biological tissue: principles and applications. Handbook of Coherent-Domain Optical Methods: Biomedical Diagnostics, Environmental and Material Science, 1, 93-138.
Angelsky, O. V., Ushenko, A. G., Ushenko, Y. A., Pishak, V. P., & Peresunko, A. P. (2010). Statistical, correlation, and topological approaches in diagnostics of the structure and physiological state of birefringent biological tissues. In Handbook of Photonics for Biomedical Science (pp. 283-322). CRC Press.
Ushenko, Y. A., Boychuk, T. M., Bachynsky, V. T., & Mincer, O. P. (2013). Diagnostics of structure and physiological state of birefringent biological tissues: statistical, correlation and topological approaches. Handbook of Coherent-Domain Optical Methods: Biomedical Diagnostics, Environmental Monitoring, and Materials Science.
Ushenko, V. A., & Gavrylyak, M. S. (2013, September). Azimuthally invariant Mueller-matrix mapping of biological tissue in differential diagnosis of mechanisms protein molecules networks an sotropy. In Biosensing and Nanomedicine VI (Vol. 8812, p. 88120Y). International Society for Optics and Photonics. стр. 6-9.
Криволапов, Ю. А., & Леенман, Е. Е. (2006). Морфологическая диагностика лимфом. КОСТА. ст.6-9
Зинкин, А. Н., Зингилевская, Н. Г., & Мусельян, Б. Б. (1997). Криовоздействие в оториноларингологии. Методические рекомендации.
Davis, D. A., Pellowski, D. M., & William Hanke, C. (2004). Preparation of frozen sections. Dermatologic surgery, 30(12p1), 1479-1485.
Ushenko, V. A., & Gorsky, M. P. (2013). Complex degree of mutual anisotropy of linear birefringence and optical activity of biological tissues in diagnostics of prostate cancer. Optics and Spectroscopy, 115(2), 290 297.
Ushenko, V. A., & Dubolazov, A. V. (2013, September). Correlation and self similarity structure of polycrystalline network biological layers Mueller matrices images. In Applications of Digital Image Processing XXXVI (Vol. 8856, p. 88562D). International Society for Optics and Photonics.
Ushenko, Y. A., Ushenko, V. A., Dubolazov, A. V., Balanetskaya, V. O., & Zabolotna, N. I. (2012). Mueller-matrix diagnostics of optical properties of polycrystalline networks of human blood plasma. Optics and Spectroscopy, 112(6), 884-892.
Ushenko, Y. A., Dubolazov, A. V., Balanetskaya, V. O., Karachevtsev, A. O., & Ushenko, V. A. (2012). Wavelet-analysis of polarization maps of human blood plasma. Optics and Spectroscopy, 113(3), 332-343.
Ushenko, V. O. (2013). Spatial-frequency polarization phasometry of biological polycrystalline networks. Optical Memory and Neural Networks, 22(1), 56-64.
Ushenko, V. A., Pavlyukovich, N. D., & Trifonyuk, L. (2013). Spatial-frequency azimuthally stable cartography of biological polycrystalline networks. International Journal of Optics, 2013, 683174. doi: 10.1155/2013/683174.
Ungurian, V. P., Ivashchuk, O. I., & Ushenko, V. O. (2011, November). Statistical analysis of polarizing maps of blood plasma laser images for the diagnostics of malignant formations. In Tenth International Conference on Correlation Optics (Vol. 8338, p. 83381L). International Society for Optics and Photonics.
Ushenko, V. A., Dubolazov, O. V., & Karachevtsev, A. O. (2014). Two wavelength Mueller matrix reconstruction of blood plasma films polycrystalline structure in diagnostics of breast cancer. Applied optics, 53(10), B128-B139.
Prysyazhnyuk, V. P., Ushenko, Y. A., Dubolazov, A. V., Ushenko, A. G., & Ushenko, V. A. (2016). Polarization-dependent laser autofluorescence of the polycrystalline networks of blood plasma films in the task of liver pathology differentiation. Applied optics, 55(12), B126-B132.
Robinson, S. P. (Ed.). (1996). Principles of forensic medicine. Cambridge University Press.
Authors who publish with this journal agree to the following terms:
- Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
- Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
- Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).