Персона: Поминова, Дарья Вячеславовна
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Инженерно-физический институт биомедицины
Цель ИФИБ и стратегия развития – это подготовка высококвалифицированных кадров на базе передовых исследований и разработок новых перспективных методов и материалов в области инженерно-физической биомедицины. Занятие лидерских позиций в биомедицинских технологиях XXI века и внедрение их в образовательный процесс, что отвечает решению практикоориентированной задачи мирового уровня – диагностике и терапии на клеточном уровне социально-значимых заболеваний человека.
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- ПубликацияТолько метаданныеFluorescence diagnostics and photodynamic therapy of grain crops pathogenic fungi(2020) Bikmukhametova, I. R.; Akhlyustina, E. V.; Pominova, D. V.; Ryabova, A. V.; Grachev, P. V.; Makarov, V. I.; Kartabaeva, B. B.; Ахлюстина, Екатерина Витальевна; Поминова, Дарья Вячеславовна; Рябова, Анастасия Владимировна; Макаров, Владимир Игоревич© 2020 IEEE.The studies show the dynamics of photosensitizers accumulation in various grain areas during germination and their photodynamic activity against pathogenic microflora (Fusarium, Bipolaris, Alternaria). Four photosensitizers (methylene blue, Chlorin E6, aluminum phthalocyanine in molecular- and nanoform) were used in the work. The accumulation level of methylene blue and aluminum phthalocyanine in molecular form in infected by Alternaria and Fusarium fungi grains was 4-5 times higher than in control on the 4th day. The possibility of pathogenic microflora inactivation using aluminum phthalocyanine was shown.
- ПубликацияТолько метаданныеSTUdy OF ENERGy TRANSFER pROCESSES BETWEEN RARE EARTh IONS ANd phOTOSENSITIZER mOLECULES FOR phOTOdyNAmIC ThERApy WITh IR-EXCITATION ИССЛЕдОвАНИЕ пРОЦЕССОв пЕРЕдАчИ ЭНЕРГИИ мЕЖдУ РЕдКОЗЕмЕЛЬНЫмИ ИОНАмИ И мОЛЕКУЛАмИ фОТОСЕНСИБИЛИЗАТОРОв дЛя ЗАдАч фОТОдИНАмИчЕСКОи ТЕРАпИИ С вОЗБУЖдЕНИЕм в ИК-дИАпАЗОНЕ(2021) Proydakova, V. Y.; Romanishkin, I. D.; Kuznetsov, S. V.; Lukyanets, E. A.; Pominova, D. V.; Bogatova, A. S.; Akhlyustina, E. V.; Saveleva, T. A.; Loschenov, V. B.; Поминова, Дарья Вячеславовна; Ахлюстина, Екатерина Витальевна; Савельева, Татьяна Александровна; Лощенов, Виктор Борисович© 2021 Russian Photodynamic Association. All rights reserved.Today, photodynamic therapy is one of the most promising minimally invasive methods of treatment of various diseases, including cancer. The main limitation of this method is the insufficient penetration into the tissue of laser radiation used to activate photosensitizer molecules,which makes it difficult to carry out therapy in the treatment of large or deep-seated tumors. In this regard, there is a great interest in thedevelopment of new strategies for photodynamic therapy using infrared radiation for excitation, the wavelengths of which fall into the “transparencywindow” of biological tissues. In this work, it was proposed to use upconversion NaGdF4:Yb:Er nanoparticles (UCNP), which absorbinfrared excitation and serve as a donor that transfers energy to the photosensitizer. Photosens and phthalosens were chosen as the mostpromising photosensitizers for the study. The aim of this work was to study the energy transfer processes between upconversion nanoparticlesdoped with rare-earth ions and photosensitizer molecules. in order to excite photosensitizers with IR radiation and carry out photodynamictherapy of deep-seated neoplasms. Using spectroscopic and time-resolved methods, it has been demonstrated that there is an efficientenergy transfer between upconversion particles and photosensitizers phthalosens and photosens. The calculated efficiency of energy transferby the Foerster mechanism was 41% for the UCNP + photosens system and 69% for the UCNP + phthalosens system. It has been experimentallyand theoretically proved that there is a binding of photosensitizer molecules with UCNP by means of surfactants, leading to a reductionin the distance between them, due to which effective nonradiative energy transfer is realized. The generation of singlet oxygen by the phthalosensphotosensitizer upon excitation by means of energy transfer from UCNP, excited at 980 nm wavelength of, has been demonstrated.
- ПубликацияОткрытый доступSPECTROSCOPIC STUDY OF METHYLENE BLUE PHOTOPHYSICAL PROPERTIES IN BIOLOGICAL MEDIA СПЕКТРОСКОПИЧЕСКОЕ ИССЛЕДОВАНИЕ ФОТОФИЗИЧЕСКИХ СВОИСТВ МЕТИЛЕНОВОГО СИНЕГО В БИОЛОГИЧЕСКИХ СРЕДАХ(2023) Pominova, D. V.; Ryabova, A. V.; Markova, I. V.; Akhlyustina, E. V.; Skobeltsin, A. S.; Поминова, Дарья Вячеславовна; Рябова, Анастасия Владимировна; Ахлюстина, Екатерина Витальевна; Скобельцин, Алексей СергеевичA spectroscopic study of the photophysical properties of methylene blue (MB) in aqueous solutions was carried out. Absorption and fluorescence spectra as well as fluorescence lifetime were recorded. The concentration dependence of the intensity and shape of the spectra allowed establishing the ranges of MB concentrations for in vitro and in vivo studies at which aggregation is not observed (up to 0.01 mM, which corresponds to 3.2 mg/kg). Studies of photodegradation in biological media showed that photobleaching of more than 80% in plasma and culture media is observed already at a dose of 5 J/cm2 , while in water at this concentration and dose photobleaching is not yet observed, and at a dose of 50 J/cm2 photobleaching of MB is about 30%. It was found that in media containing proteins and having an alkaline pH, photobleaching occurs significantly faster than in neutral aqueous media. The ionic strength of the solution has no effect on the photobleaching rate. Such photobleaching is caused by the photodegradation of MB rather than the transition to the leucoform.The efficiency of singlet oxygen generation and photodynamic activity were evaluated in vitro. In the investigated range of MB concentrations, the efficiency of singlet oxygen generation is rather low, because positively charged MB binds to negatively charged cell membranes, which leads to a change in the type of photodynamic reaction. The emergence of other reactive oxygen species (ROS), different from singlet oxygen, in cells has been demonstrated. The generation of ROS and the low quantum yield of singlet oxygen generation indicate the tendency of MB to provide the type I photosensitization mechanism (electron transfer with the formation of semi-reduced and semi-oxidized MB+ radicals) rather than to the type II mechanism (energy transfer to oxygen with the formation of singlet oxygen) in biological media and in vivo.