Prof. Aliaksander V. Bykau Profile

Prof. Aliaksander V. Bykau

Adj. Professor at University of Oulu

SPIE Involvement:

Author

Publications (91)

Proceedings Article | 27 November 2023 Poster + Paper

Acousto-optic sensing: tagging efficiency in long coherent laser versus laser diode and LED

Mohammadreza Omidali, Triana Rahayu, Zuomin Zhao, Sadegh Moradi, Alexander Bykov, Teemu Myllylä

Proceedings Volume 12766, 1276610 (2023) https://doi.org/10.1117/12.2687676

KEYWORDS: Acousto-optics, Light emitting diodes, Signal detection, Light sources, Acoustooptics, Tissues, Modulation

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SPIE Journal Paper | 21 November 2023 Open Access

Exploring the evolution of circular polarized light backscattered from turbid tissue-like disperse medium utilizing generalized Monte Carlo modeling approach with a combined use of Jones and Stokes–Mueller formalisms

Ivan Lopushenko, Oleksii Sieryi, Alexander Bykov, Igor Meglinski

JBO, Vol. 29, Issue 05, 052913, (November 2023) https://doi.org/10.1117/12.10.1117/1.JBO.29.5.052913

KEYWORDS: Polarization, Polarized light, Sensors, Turbidity, Mueller matrices, Light scattering, Scattering, Tissues, Depolarization, Monte Carlo methods

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SignificancePhase retardation of circularly polarized light (CPL), backscattered by biological tissue, is used extensively for quantitative evaluation of cervical intraepithelial neoplasia, presence of senile Alzheimer’s plaques, and characterization of biotissues with optical anisotropy. The Stokes polarimetry and Mueller matrix approaches demonstrate high potential in definitive non-invasive cancer diagnosis and tissue characterization. The ultimate understanding of CPL interaction with tissues is essential for advancing medical diagnostics, optical imaging, therapeutic applications, and the development of optical instruments and devices.AimWe investigate propagation of CPL within turbid tissue-like scattering medium utilizing a combination of Jones and Stokes–Mueller formalisms in a Monte Carlo (MC) modeling approach. We explore the fundamentals of CPL memory effect and depolarization formation.ApproachThe generalized MC computational approach developed for polarization tracking within turbid tissue-like scattering medium is based on the iterative solution of the Bethe–Salpeter equation. The approach handles helicity response of CPL scattered in turbid medium and provides explicit expressions for assessment of its polarization state.ResultsEvolution of CPL backscattered by tissue-like medium at different conditions of observation in terms of source–detector configuration is assessed quantitatively. The depolarization of light is presented in terms of the coherence matrix and Stokes–Mueller formalism. The obtained results reveal the origins of the helicity flip of CPL depending on the source–detector configuration and the properties of the medium and are in a good agreement with the experiment.ConclusionsBy integrating Jones and Stokes–Mueller formalisms, the combined MC approach allows for a more complete representation of polarization effects in complex optical systems. The developed model is suitable to imitate propagation of the light beams of different shape and profile, including Gaussian, Bessel, Hermite–Gaussian, and Laguerre–Gaussian beams, within tissue-like medium. Diverse configuration of the experimental conditions, coherent properties of light, and peculiarities of polarization can be also taken into account.

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SPIE Journal Paper | 14 November 2023 Open Access

Incremental residual polarization caused by aging in human skin

Viktor Dremin, Elena Zharkikh, Ivan Lopushenko, Zbignevs Marcinkevics, Alexander Bykov, Igor Meglinski

JBO, Vol. 29, Issue 05, 052912, (November 2023) https://doi.org/10.1117/12.10.1117/1.JBO.29.5.052912

KEYWORDS: Polarization, Skin, Scattering, Tissues, Absorption, Light scattering, Collagen, Polarized light, Blood, Optical properties

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Proceedings Article | 5 October 2023 Presentation

Optical biopsy and biomedical diagnosis with circular polarisation and orbital angular momentum of light

Igor Meglinski, Ivan Lopushenko, Anton Sdobnov, Alexander Bykov

Proceedings Volume PC12690, PC1269004 (2023) https://doi.org/10.1117/12.2674384

KEYWORDS: Biomedical optics, Polarized light, Polarization, Angular momentum, Tissues, Biopsy, Tissue optics, Light scattering, Laser scattering, Depolarization

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SPIE Journal Paper | 8 July 2023 Open Access

Mueller-matrix imaging polarimetry elevated by wavelet decomposition and polarization-singular processing for analysis of specific cancerous tissue pathology

Anton Sdobnov, Volodymir A. Ushenko, Liliya Trifonyuk, Oksana Bakun, Marta Garazdyuk, Irina V. Soltys, Olexander Dubolazov, Olexander G. Ushenko, Yuriy A. Ushenko, Alexander Bykov, Igor Meglinski

JBO, Vol. 28, Issue 10, 102903, (July 2023) https://doi.org/10.1117/12.10.1117/1.JBO.28.10.102903

KEYWORDS: Tissues, Wavelets, Polarimetry, Biomedical optics, Prostate, Biological samples, Tissue optics, Statistical analysis, Polarization, Actinium

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Proceedings Article | 31 May 2023 Poster + Paper

Brillouin interaction between single optical modes excited in multimode fibers

Andrei Fotiadi, Edik Rafailov, Dmitry Korobko, Ivan Chapalo, Patrice Mégret, Alexander Bykov, Igor Meglinski

Proceedings Volume 12572, 125721L (2023) https://doi.org/10.1117/12.2665904

KEYWORDS: Optical fibers, Multimode fibers, Acoustic waves, Wave propagation, Planar waveguides, Laser scattering, Diffraction, Singular optics, Single mode fibers, Fiber lasers

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SPIE Journal Paper | 14 March 2023

Terahertz-to-infrared converters for imaging the human skin cancer: challenges and feasibility

Kamil Moldosanov, Alexander Bykov, Nurlanbek Z. Kairyev, Mikhail Khodzitsky, Grigory Kropotov, Valery Lelevkin, Igor Meglinski, Andrei Postnikov, Alexey Shakhmin

JMI, Vol. 10, Issue 02, 023501, (March 2023) https://doi.org/10.1117/12.10.1117/1.JMI.10.2.023501

KEYWORDS: Terahertz radiation, Phonons, Infrared cameras, Gold nanoparticles, Cameras, Photons, Gold, Matrices, Infrared imaging, Alloys

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Proceedings Article | 9 March 2023 Poster + Paper

Light source-detector pair positioning to optimize tagging efficiency of focused ultrasound-modulated photons in a backward detection mode

Mohammadreza Omidali, Ali Mardanshahi, Zuomin Zhao, Deepak Sonker, Alexander Bykov, Teemu Myllylä

Proceedings Volume 12379, 123791N (2023) https://doi.org/10.1117/12.2650594

KEYWORDS: Photons, Simulations, Acoustics, Transducers, Tissues, Monte Carlo methods, Light sources and illumination, Ultrasonics

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Proceedings Article | 7 March 2023 Presentation

Deep learning for hyperspectral imaging of human skin and automated extraction of its functional and optical properties

Alexander Doronin, Igor Meglinski, Alexander Bykov

Proceedings Volume PC12378, PC1237807 (2023) https://doi.org/10.1117/12.2649398

KEYWORDS: Skin, Hyperspectral imaging, Optical properties, Tissue optics, Tissues, Data processing, Multiple scattering, Monte Carlo methods, Machine learning, Light scattering

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Proceedings Article | 3 October 2022 Presentation

Hemorheological alterations of erythrocytes induced by plasmonic nanoparticles assessed with the combined application of optical tweezers and conventional microscopy modalities

Tatiana Avsievich, Alexander Bykov, Anton Popov, Andrei Kabashin, Igor Meglinski

Proceedings Volume PC12198, PC121980A (2022) https://doi.org/10.1117/12.2634990

KEYWORDS: Plasmonics, Optical tweezers, Nanoparticles, Microscopy, Therapeutics, Interfaces, Infrared lasers, Diagnostics, Blood

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Proceedings Article | 30 May 2022 Presentation

The roles of birefringence and scattering of polarized light in visual perception of the entopic phenomena: Haidinger's and Boehm’s brushes

Igor Meglinski, Ivan Lopushenko, Alexander Bykov, Gary Misson, Stephen Anderson

Proceedings Volume PC12147, PC1214704 (2022) https://doi.org/10.1117/12.2621205

KEYWORDS: Light scattering, Visualization, Scattering, Birefringence, Monte Carlo methods, Macula, Retina, Polarization, Modeling, Eye models

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Proceedings Article | 29 April 2022 Paper

Low-cost fabrication of PPIX liquid phantoms for use in fluorescence measurements

Valery Shupletsov, Margarita Mikenkina, Evgeny Zherebtsov, Viktor Dremin, Alexander Bykov, Elena Potapova, Andrey Dunaev, Igor Meglinski

Proceedings Volume 12192, 121920U (2022) https://doi.org/10.1117/12.2626389

KEYWORDS: Liquids, Optical phantoms, Spectroscopy, Manufacturing, Optics manufacturing, Imaging systems

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Proceedings Article | 7 March 2022 Presentation

Polarimentric differentiation of ex vivo colon samples complemented by machine-learning

Deyan Ivanov, Viktor Dremin, Tsanislava Genova, Alexander Bykov, Igor Meglinski, Tatiana Novikova, Razvigor Ossikovski

Proceedings Volume PC11963, PC1196307 (2022) https://doi.org/10.1117/12.2615297

KEYWORDS: Polarimetry, Colon, Tissue optics, Tumors, Tissues, Principal component analysis, Polarization, Optical spheres, Diagnostics

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Proceedings Article | 7 December 2021 Paper

Digital histo-biophotonics: embossed topographic depolarization mapping of tissue samples

A. Grechina, A. Venediktov, G. Piavchenko, T. Boronikhina, V. Ushenko, A. Dubolazov, M. Gorsky, A. Ushenko, Yu. Ushenko, A. Bykov, S. Kuznetsov, I. Meglinski

Proceedings Volume 11919, 1191912 (2021) https://doi.org/10.1117/12.2614795

KEYWORDS: Tissues, Liver, Tissue optics, Geometrical optics, Active optics, Polarization, Polarimetry, Beam splitters, Statistical analysis, Scattering

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Proceedings Article | 7 December 2021 Paper

Histological imaging of unstained cancer tissue samples by circularly polarized light

Viktor Dremin, Oleksii Sieryi, Mariia Borovkova, Juha Näpänkangas, Igor Meglinski, Alexander Bykov

Proceedings Volume 11919, 119190F (2021) https://doi.org/10.1117/12.2614468

KEYWORDS: Tissues, Polarization, Cancer, Tissue optics, Image segmentation, Breast cancer, Poincaré sphere, Statistical analysis, Scattering, Polarimetry

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Proceedings Article | 7 December 2021 Paper

Assessment of the Alzheimer progression with multiwavelength Stokes polarimetry

Mariia Borovkova, Oleksii Sieryi, Jens Pahnke, Alexander Bykov, Igor Meglinski

Proceedings Volume 11919, 119190U (2021) https://doi.org/10.1117/12.2614594

KEYWORDS: Tissues, Brain, Polarimetry, Polarization, Alzheimer's disease, Statistical analysis, Neuroimaging, Tunable filters, OSLO, Beam splitters

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Proceedings Article | 12 September 2021 Presentation + Paper

Terahertz-to-infrared converter based on the polyvinylchloride matrix with embedded gold nanoparticles

K. Moldosanov, A. Bykov, N. Kairyev, M. Khodzitsky, G. Kropotov, V. Lelevkin, I. Meglinski, A. Postnikov, A. Shakhmin, O. Sieryi

Proceedings Volume 11868, 118680S (2021) https://doi.org/10.1117/12.2602089

KEYWORDS: Nanoparticles, Phonons, Terahertz radiation, Gold, Infrared cameras, Electrons, Absorption, Photons, Infrared radiation, Metals

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Proceedings Article | 1 August 2021 Presentation + Paper

In vitro influence of 520 nm diode laser irradiation on red blood cell spontaneous aggregation studied by optical tweezers and light microscopy

Ruixue Zhu, Tatiana Avsievich, Alexey Popov, Alexander Bykov, Igor Meglinski

Proceedings Volume 11798, 1179809 (2021) https://doi.org/10.1117/12.2595118

KEYWORDS: Blood, Laser irradiation, Optical tweezers, Plasma, Laser tissue interaction, Laser therapeutics, Laser applications, In vitro testing, Microscopy

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Proceedings Article | 5 March 2021 Presentation + Paper

Symmetric decomposition of Mueller matrices reveals a new parametric space for polarimetric assistance in colon cancer histopathology

Deyan Ivanov, Viktor Dremin, Ekaterina Borisova, Alexander Bykov, Igor Meglinski, Tatiana Novikova, Razvigor Ossikovski

Proceedings Volume 11646, 1164614 (2021) https://doi.org/10.1117/12.2578090

KEYWORDS: Polarimetry, Colon, Tissues, Monte Carlo methods, Photon transport, Algorithm development, Tissue optics, Optical properties, Matrices, Gold

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SPIE Journal Paper | 17 November 2020 Open Access

Development of oral cancer tissue-mimicking phantom based on polyvinyl chloride plastisol and graphite for terahertz frequencies

Tianmiao Zhang, Ravshanjon Nazarov, Alexey Popov, Petr Demchenko, Alexander Bykov, Roman Grigorev, Anna Kuzikova, Victoria Soboleva, Dmitrii Zykov, Igor Meglinski, Mikhail K. Khodzitskiy

JBO, Vol. 25, Issue 12, 123002, (November 2020) https://doi.org/10.1117/12.10.1117/1.JBO.25.12.123002

KEYWORDS: Terahertz radiation, Optical properties, Tissues, Absorption, Refractive index, Cancer, Tissue optics, Particles, Error analysis, Water

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Proceedings Article | 20 August 2020 Presentation

Cloud-based online application for imitation of polarized light propagation in turbid scattering media

Alexander Doronin, Hee Ryung Lee, Igor Meglinski, Alexander Bykov, Tatiana Novikova

Proceedings Volume 11484, 1148409 (2020) https://doi.org/10.1117/12.2568271

KEYWORDS: Scattering media, Light scattering, Tissues, Optical coherence tomography, Monte Carlo methods, Tissue optics, Polarization, Optical diagnostics, Polarimetry, Backscatter

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SPIE Journal Paper | 20 May 2020 Open Access

Role of scattering and birefringence in phase retardation revealed by locus of Stokes vector on Poincaré sphere

Mariia Borovkova, Alexander Bykov, Alexey Popov, Igor Meglinski

JBO, Vol. 25, Issue 05, 057001, (May 2020) https://doi.org/10.1117/12.10.1117/1.JBO.25.5.057001

KEYWORDS: Scattering, Light scattering, Birefringence, Tissues, Skin, Poincaré sphere, Optical clearing, Polarization, Polarimetry, Tissue optics

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Significance: Biological tissues are typically characterized by high anisotropic scattering and may also exhibit linear form birefringence. Both scattering and birefringence bias the phase shift between transverse electric field components of polarized light. These phase alterations are associated with particular structural malformations in the tissue. In fact, the majority of polarization-based techniques are unable to distinguish the nature of the phase shift induced by birefringence or scattering of light. Aim: We explore the distinct contributions of scattering and birefringence in the phase retardation of circularly polarized light propagated in turbid tissue-like scattering medium. Approach: The circularly polarized light in frame of Stokes polarimetry approach is used for the screening of biotissue phantoms and chicken skin samples. The change of optical properties in chicken skin is accomplished by optical clearing, which reduces scattering, and mechanical stretch, which induces birefringence. The change of optical properties of skin tissue is confirmed by spectrophotometric measurements and second-harmonic generation imaging. Results: The contributions of scattering and birefringence in the phase retardation of circularly polarized light propagated in biological tissues are distinguished by the locus of the Stokes vector mapped on the Poincaré sphere. The phase retardation of circularly polarized light due to scattering alterations is assessed. The value of birefringence in chicken skin is estimated as 0.3 × 10 − 3, which agrees with alternative studies. The change of birefringence of skin tissue due to mechanical stretch in the order of 10 − 6 is detected. Conclusions: While the polarimetric parameters on their own do not allow distinguishing the contributions of scattering and birefringence, the resultant Stokes vector trajectory on the Poincaré sphere reveals the role of scattering and birefringence in the total phase retardation. The described approach, applied independently or in combination with Mueller polarimetry, can be beneficial for the advanced characterization of various types of malformations within biological tissues.

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Proceedings Article | 12 May 2020 Presentation + Paper

Tissue-mimicking phantoms for biomedical applications

Oleksii Sieryi, Alexey Popov, Vyacheslav Kalchenko, Alexander Bykov, Igor Meglinski

Proceedings Volume 11363, 1136312 (2020) https://doi.org/10.1117/12.2560174

KEYWORDS: Tissues, Biomedical optics, Optical properties, Zinc oxide, Systems modeling, Silicon, Particles, Head, Capillaries, Diagnostics

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Proceedings Article | 27 April 2020 Presentation

Polarization-sensitive hyperspectral imaging of human skin: From system design to clinical validation (Conference Presentation)

Alexander Bykov, Viktor Dremin, Zbignevs Marcinkevics, Evgenii Zherebtsov, Alexander Doronin, Alexey Popov, Andris Grabovskis, Igor Meglinski

Proceedings Volume 11389, 1138914 (2020) https://doi.org/10.1117/12.2556842

KEYWORDS: Skin, Hyperspectral imaging, Imaging systems, Reflectivity, Polarization, Cameras, Fiber optic illuminators, Polarizers, Blood, Algorithm development

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Proceedings Article | 7 April 2020 Presentation + Paper

Imaging of early stage breast cancer with circularly polarized light

Viktor Dremin, Dmytro Anin, Oleksii Sieryi, Mariia Borovkova, Juha Näpänkangas, Igor Meglinski, Alexander Bykov

Proceedings Volume 11363, 1136304 (2020) https://doi.org/10.1117/12.2554166

KEYWORDS: Breast cancer, Cancer, Polarization, Diagnostics, Tissues, Light scattering, Biological research, Breast, Polarimetry

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Proceedings Article | 9 March 2020 Presentation

GPU-accelerated online Monte Carlo (MC) application for imitation of twisted light propagation in turbid tissue-like scattering media (Conference Presentation)

Alexander Doronin, Hee Ryung Lee, Tatiana Novikova, Nicolás Vera, Juan Pablo Staforelli, Alexander Bykov, Igor Meglinski

Proceedings Volume 11234, 112340K (2020) https://doi.org/10.1117/12.2545779

KEYWORDS: Monte Carlo methods, Tissue optics, Scattering media, Tissues, Optical diagnostics, Biomedical optics, Image processing, Multiple scattering, Light scattering, Stochastic processes

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Proceedings Article | 21 February 2020 Presentation + Paper

Wireless data transfer through biological tissues using near-infrared light: testing skull and skin phantoms

Iqrar Ahmed, Alexander Bykov, Alexey Popov, Igor Meglinski, Marcos Katz

Proceedings Volume 11226, 1122615 (2020) https://doi.org/10.1117/12.2545221

KEYWORDS: Skull, Tissues, Skin, Light emitting diodes, Receivers, RF communications, Modulation, Near infrared, Safety, Optical communications

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Proceedings Article | 21 February 2020 Presentation + Paper

The use of Stokes-Mueller polarimetry for assessment of amyloid-β progression in a mouse model of Alzheimer’s disease

Mariia Borovkova, Alexander Bykov, Alexey Popov, Angelo Pierangelo, Tatiana Novikova, Jens Pahnke, Igor Meglinski

Proceedings Volume 11234, 112340M (2020) https://doi.org/10.1117/12.2550795

KEYWORDS: Brain, Polarimetry, Polarization, Tissues, Alzheimer's disease, Statistical analysis, Mouse models, Light scattering, Poincaré sphere, Scattering

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Proceedings Article | 30 December 2019 Paper

Assessment of pork freshness based on changes in constituting chromophores using visible to near-infrared spectroscopy

M. Peyvasteh, A. Popov, A. Bykov, I. Meglinski

Proceedings Volume 11202, 112020X (2019) https://doi.org/10.1117/12.2539969

KEYWORDS: Absorbance, Visible radiation, Chromophores, Proteins, Near infrared, Near infrared spectroscopy, Fiber optics, Integrating spheres, Spectroscopy, Oxidation

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Proceedings Article | 12 September 2019 Presentation

Meat freshness evaluation using visible to near-infrared spectroscopy (Conference Presentation)

Motahareh Peyvasteh, Alexey Popov, Alexander Bykov, Igor Meglinski

Proceedings Volume 11130, 1113002 (2019) https://doi.org/10.1117/12.2528396

KEYWORDS: Visible radiation, Near infrared spectroscopy, Absorbance, Spectrophotometry, Fiber optics, Near infrared, Proteins, Integrating spheres, Nondestructive evaluation

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Proceedings Article | 9 September 2019 Presentation

Study of mutual interaction of red blood cells influenced by nanoparticles utilizing a combined use of optical tweezers and scanning electron microscopy (Conference Presentation)

Tatiana Avsievich, Alexey Popov, Ruixue Zhu, Alexander Bykov, Igor Meglinski

Proceedings Volume 11083, 110830I (2019) https://doi.org/10.1117/12.2528193

KEYWORDS: Nanoparticles, Blood, Optical tweezers, Scanning electron microscopy, Polymers, Medicine, Microscopy, Plasma, Particles, Nanomaterials

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