APPLICATION OF DEVICES FOR SPACE-RESOLVED SPECTROSCOPY ON THE EXAMPLE OF TWO-LAYER PHANTOMS CONTAINING METALLIC NANOPARTICLES ; ПРИМЕНЕНИЕ УСТРОЙСТВ ДЛЯ ПРОСТРАНСТВЕННО-РАЗРЕШЕННОЙ СПЕКТРОСКОПИИ НА ПРИМЕРЕ ДВУХСЛОЙНЫХ ФАНТОМОВ, СОДЕРЖАЩИХ МЕТАЛЛИЧЕСКИЕ НАНОЧАСТИЦЫ

Authors: M. N. Kholodtsova, P. V. Grachev, W. C. Blondel, P. V. Zelenkov, A. A. Potapov, I. A. Shcherbakov, V. B. Loschenov, М. Н. Холодцова, П. В. Грачев, В. C. Блондель, П. В. Зеленков, А. А. Потапов, И. А. Щербаков, В. Б. Лощенов

Source: Biomedical Photonics; Том 7, № 2 (2018); 4-12 ; 2413-9432 ; 10.24931/2413-9432-2018-7-2

Subject Terms: флуоресцентная спектроскопия, metal nanoparticles, optical probing depth, fluorescence probing depth, glial tumours, biological tissue, multi-layered tissue, spatially resolved spectroscopy, 5-aminolevulinic acid, protoporphyrin IX, stereotactic biopsy, fluorescence spectroscopy, наночастицы металлов, глубина оптического зондирования, глубина зондирования флуоресценции, глиальные опухоли, биологическая ткань, многослойная ткань, пространственно разрешенная спектроскопия, 5-аминолевулиновая кислота, протопорфирин IX, стереотактическая биопсия

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Relation: https://www.pdt-journal.com/jour/article/view/231/185; Champion J., Katare Y., Mitragotri S. Particle shape: A new design parameter for micro- and nanoscale drug delivery carriers // Jour- nal of Controlled Release. – 2007. – Vol. 121. – P. 3–9.; Weibo C., Ting G., Hao H., Sun J. Applications of gold nanopar- ticles in cancer and nanotechnology // Nanotechnology, Science and Applications. – 2008. – № 1. – P. 17–32.; Bohren C., Huffman D. Absorption and Scattering of Light by Small Particles. – Wiley, VCH Verlag GmbH, 1998. – 545 p.; Cihan C., Arifler D. Influence of phase function on modeled opti- cal response of nanoparticle-labeled epithelial tissues // Journal of Biomedical Optics. – 2011. – Vol. 16(8). – 085002.; Потапов А.А., Гаврилов А.Г., Горяйнов С.А. и др. Способ проведения интраоперационной комбинированной спектроскопической диагностики опухолей головного и спинного мозга Simultanious parenchymal organ biopsy and spectroscopic inspection device. – Патент РФ №2497558, 2013. – 16 с.; Markwardt N.A., Haj-Hosseini N., Hollnburger B., et al. 405 nm versus 633 nm for protoporphyrin IX excitation in fluorescence- guided stereotactic biopsy of brain tumors // Journal of Biopho- tonics. – 2015. – Vol. 9(9). – P. 901–912.; Blondel W.C., Ghribi M., Leroux A., et al. Spectral features selec- tion and classification for bimodal optical spectroscopy applied to bladder cancer in vivo diagnosis // IEEE Transactions on Biomedi- cal Engineering. – 2014. – Vol 61(1). – P. 207–216.; Rick K., Sroka R., Stepp H., Kriegmair M., et al. Pharmacokinetics of 5-aminolevulinic acid-induced protoporphyrin ix in skin and blood // Journal of Photochemistry and Photobiology B-Biology. – 1997. – Vol. 40(3). – P. 313–319.; Wuithschick M., Birnbaum A., Witte S., et al. Turkevich in new robes: Key questions answered for the most common gold nanoparticle synthesis // ACS Nano. – 2015. – Vol. 9(7). – P. 7052–7071.; Hrelescu C., Sau T.K. Selective excitation of individual plasmonic hotspots at the tips of single gold nanostars // Nano Letters. –2011. – Vol. 11. – P. 402–407.; Scaffard L., Tocho J. Size dependence of refractive index of gold nanoparticles // Nanotechnology. – 2006. – Vol. 17. – P. 1309–1315.; Kholodtsova M., Samsonova I., Blondel W., Loschenov V. Metal nanoparticles of different shapes influence on optical properties of multilayered biological tissues // Proceedings of SPIE. -2015. – Vol. 9542. – 954205.; Kang K., Wang J., Jasinski J., Achilefu S. Fluorescence manipulation by gold nanoparticles: From complete quenching to extensive enhance- ment // Journal of Nanobiotechnology. – 2011. – Vol. 9. – P. 16.; Ninni P.D., Martelli F., Zaccanti G. The use of India Ink in tissue-simu- lating phantoms // Optics Express. – 2010. – Vol. 18(26). – P. 26854–26865.; Ninni P.D., Martelli, F., Zaccanti G. Intralipid: towards a diffusive ref- erence standard for optical tissue phantoms // Physics in Medicine and Biology. – 2011. – Vol. 56. – P. 21–28.; Flock S.T., Jacques S.L., Wilson B.C., et al. Optical properties of intralipid: A phantom medium for light propagation studies // Lasers in Surgery and Medicine. – 1992. – Vol. 12(5) – P.510–519.; Yaroslavsky N., Schulze P., Yaroslavsky I.V., et al. Optical properties of selected native and coagulated human brain tissues in vitro in the visible and near infrared spectral range // Physics in Medicine and Biology. – 2002. – Vol. 47(12). – P. 2059–2073.; Bashkatov, A., Genina, E., Tuchin, V., Optical properties of skin, subcutaneous, and muscle tissues: a review // Journal of Innova- tive Optical Health Science. – 2011. – Vol. 04(01). – P.9–38.; Kholodtsova M.N., Grachev P.V., Savelieva T.A., et al. Scattered and fluorescent photon track reconstruction in a biological tissue // International Journal of Photoenergy. – 2014. – 517510.; Haiss W., Thanh N., Aveyard J., Fernig, D. Determination of size and concentration of gold nanoparticles from uv-vis spectra // Ana- lytical Chemistry. – 2007. – Vol. 79. – P.4215–4221.

Availability: https://www.pdt-journal.com/jour/article/view/231
https://doi.org/10.24931/2413-9432-2018-7-2-4-12

Развитие оптических методов диагностики биологических тканей по рассеянному излучению. ІІ. Поляризационная пространственно-разрешающая спектроскопия

Authors: Барун, В. В., Иванов, А. П., Петрук, В. Г., Кватернюк, С. М., Іванов, А. П., Barun, V. V., Ivanov, A. P., Petruk, V. G., Kvaternyuk, S. M.

Subject Terms: биологические ткани, рассеяное излучение, оптические методы диагностики, поляризационная и пространственно-разрешенная спектроскопия

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Relation: http://ir.lib.vntu.edu.ua/handle/123456789/1082; 535.36

Availability: http://ir.lib.vntu.edu.ua/handle/123456789/1082