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Кабашин, Андрей Викторович

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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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Руководитель научной группы "Лаборатория «Бионанофотоники"
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Кабашин
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Андрей Викторович
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Теперь показываю 1 - 7 из 7
  • Публикация
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    Создание композитов Bi@SiO2 со структурой ядро@оболочка на основе лазерно-синтезированных наночастиц Bi
    (2023) Скрибицкая, А. В.; Короткова, Н. А.; Котельникова, П. А.; Тихоновский, Г. В.; Попов, А. А.; Климентов, С. М.; Завестовская, И. Н.; Кабашин, А. В.; Завестовская, Ирина Николаевна; Кабашин, Андрей Викторович; Климентов, Сергей Михайлович; Попов, Антон Александрович; Скрибицкая, Ангелина Вячеславовна; Тихоновский, Глеб Валерьевич
    Разработана методика получения нанокомпозитов по типу ядро@оболочка путём поверхностной модификации лазерно-синтезированных наночастиц (НЧ) висмута тетраэтоксисиланом с конечной структурной формулой Bi@SiO2. Показано, что покрытие НЧ Bi оболочкой из SiO2 приводит к образованию сферических наноформуляций с модой размерного распределения 250 – 300 нм. Разработанная методика, позволяющая создавать биосовместимые нанокомпозиты на основе Bi для сенсибилизации мультимодальной тераностики, является новой перспективной альтернативой традиционным методам.
  • Публикация
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    Pентгеноконтрастные свойства наноформуляций на основе висмута
    (2023) Савинов, М. С.; Грязнова, О. Ю.; Тихоновский, Г. В.; Попов, А. А.; Завестовская, И. Н.; Климентов, С. М.; Кабашин, А. В.; Завестовская, Ирина Николаевна; Кабашин, Андрей Викторович; Климентов, Сергей Михайлович
    Исследуется возможность использования наночастиц элементного висмута в качестве сенсибилизаторов радиационной терапии и контрастных агентов компьютерной томографии. Проводится сравнительный анализ рентгеноконтрастных свойств наночастиц висмута с классическими наночастицами золота и нанолистами оксихлорида висмута. Показано, что лазерно-синтезированные наночастицы висмута демонстрируют более высокую эффективность контрастирования рентгеновского излучения по сравнению с традиционными наночастицами золота, а также обладают схожими рентгеноконтрастными свойствами с химически синтезированными аналогами на основе нанолистов оксихлорида висмута. Уникальные физико-химические характеристики в сочетании с высокими рентгеноконтрастными свойствами лазерно-синтезированных наночастиц висмута формируют новую перспективную альтернативу традиционным сенсибилизаторам радиационной тераностики онкологических заболеваний.
  • Публикация
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    Nuclear nanomedicine using Si nanoparticles as safe and effective carriers of 188 Re radionuclide for cancer therapy
    (2019) Tischenko, V. K.; Mikhailovskaya, A. A.; Popov, A. A.; Tselikov, G.; Petriev, V. M.; Deyev, S. M.; Timoshenko, V. Y.; Prasad, P. N.; Zavestovskaya, I. N.; Kabashin, A. V.; Деев, Сергей Михайлович; Тимошенко, Виктор Юрьевич; Завестовская, Ирина Николаевна; Кабашин, Андрей Викторович
    © 2019, The Author(s). Nuclear nanomedicine, with its targeting ability and heavily loading capacity, along with its enhanced retention to avoid rapid clearance as faced with molecular radiopharmaceuticals, provides unique opportunities to treat tumors and metastasis. Despite these promises, this field has seen limited activities, primarily because of a lack of suitable nanocarriers, which are safe, excretable and have favorable pharmacokinetics to efficiently deliver and retain radionuclides in a tumor. Here, we introduce biodegradable laser-synthesized Si nanoparticles having round shape, controllable low-dispersion size, and being free of any toxic impurities, as highly suitable carriers of therapeutic 188 Re radionuclide. The conjugation of the polyethylene glycol-coated Si nanoparticles with radioactive 188 Re takes merely 1 hour, compared to its half-life of 17 hours. When intravenously administered in a Wistar rat model, the conjugates demonstrate free circulation in the blood stream to reach all organs and target tumors, which is radically in contrast with that of the 188 Re salt that mostly accumulates in the thyroid gland. We also show that the nanoparticles ensure excellent retention of 188 Re in tumor, not possible with the salt, which enables one to maximize the therapeutic effect, as well as exhibit a complete time-delayed conjugate bioelimination. Finally, our tests on rat survival demonstrate excellent therapeutic effect (72% survival compared to 0% of the control group). Combined with a series of imaging and therapeutic functionalities based on unique intrinsic properties of Si nanoparticles, the proposed biodegradable complex promises a major advancement in nuclear nanomedicine.
  • Публикация
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    Bi-Modal Nonlinear Optical Contrast from Si Nanoparticles for Cancer Theranostics
    (2019) Rogov, A.; Ryabchikov, Y. V.; Geloen, A.; Tishchenko, I.; Kharin, A. Y.; Lysenko, V.; Zavestovskaya, I. N.; Kabashin, A. V.; Timoshenko, V. Y.; Завестовская, Ирина Николаевна; Кабашин, Андрей Викторович; Тимошенко, Виктор Юрьевич
    © 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim Presenting a safe alternative to conventional compound quantum dots and other functional nanostructures, nanosilicon can offer a series of breakthrough hyperthermia-based therapies under near-infrared, radiofrequency, ultrasound, etc., excitation, but the size range to sensitize these therapies is typically too large (>10 nm) to enable efficient imaging functionality based on photoluminescence properties of quantum-confined excitonic states. Here, it is shown that large Si nanoparticles (NPs) are capable of providing two-photon excited luminescence (TPEL) and second harmonic generation (SHG) responses, much exceeding that of smaller Si NPs, which promises their use as probes for bi-modal nonlinear optical bioimaging. It is finally demonstrated that the combination of TPEL and SHG channels makes possible efficient tracing of both separated Si NPs and their aggregations in different cell compartments, while the resolution of such an approach is enough to obtain 3D images. The obtained bi-modal contrast provides lacking imaging functionality for large Si NPs and promises the development of novel cancer theranostic modalities on their basis.
  • Публикация
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    Laser-Processed Nanosilicon: A Multifunctional Nanomaterial for Energy and Healthcare
    (2019) Singh, A.; Swihart, M. T.; Kabashin, A. V.; Zavestovskaya, I. N.; Prasad, P. N.; Кабашин, Андрей Викторович; Завестовская, Ирина Николаевна
    Copyright © 2019 American Chemical Society.This review describes promising laser-based approaches to produce silicon nanostructures, including laser ablation of solid Si targets in residual gases and liquids and laser pyrolysis of silane. These methods are different from, and complementary to, widely used porous silicon technology and alternative synthesis routes. One can use these methods to make stable colloidal dispersions of silicon nanoparticles in both organic and aqueous media, which are suitable for a multitude of applications across the important fields of energy and healthcare. Size tailoring allows production of Si quantum dots with efficient photoluminescence that can be tuned across a broad spectral range from the visible to near-IR by varying particle size and surface functionalization. These nanoparticles can also be integrated with other nanomaterials to make multifunctional composites incorporating magnetic and/or plasmonic components. In the energy domain, this review highlights applications to photovoltaics and photodetectors, nanostructured silicon anodes for lithium ion batteries, and hydrogen generation from water. Application to nanobiophotonics and nanomedicine profits from the excellent biocompatibility and biodegradability of nanosilicon. These applications encompass several types of bioimaging and various therapies, including photodynamic therapy, RF thermal therapy, and radiotherapy. The review concludes with a discussion of challenges and opportunities in the applications of laser-processed nanosilicon.
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    Laser-ablative synthesis of isotope-enriched samarium oxide nanoparticles for nuclear nanomedicine
    (2020) Duflot, V.; Popova-Kuznetsova, E.; Tikhonowski, G.; Popov, A. A.; Deyev, S.; Klimentov, S.; Zavestovskaya, I.; Prasad, P. N.; Kabashin, A. V.; Попова-Кузнецова, Елена Алефтиновна; Тихоновский, Глеб Валерьевич; Попов, Антон Александрович; Деев, Сергей Михайлович; Климентов, Сергей Михайлович; Завестовская, Ирина Николаевна; Кабашин, Андрей Викторович
    © 2019 by the authors. Licensee MDPI, Basel, Switzerland.Nuclear nanomedicine is an emerging field, which utilizes nanoformulations of nuclear agents to increase their local concentration at targeted sites for a more effective nuclear therapy at a considerably reduced radiation dosage. This field needs the development of methods for controlled fabrication of nuclear agents carrying nanoparticles with low polydispersity and with high colloidal stability in aqueous dispersions. In this paper, we apply methods of femtosecond (fs) laser ablation in deionized water to fabricate stable aqueous dispersion of152Sm-enriched samarium oxide nanoparticles (NPs), which can capture neutrons to become153Sm beta-emitters for nuclear therapy. We show that direct ablation of a152Sm-enriched samarium oxide target leads to widely size-and shape-dispersed populations of NPs with low colloidal stability. However, by applying a second fs laser fragmentation step to the dispersion of initially formed colloids, we achieve full homogenization of NPs size characteristics, while keeping the same composition. We also demonstrate the possibility for wide-range tuning of the mean size of Sm-based NPs by varying laser energy during the ablation or fragmentation step. The final product presents dispersed solutions of samarium oxide NPs with relatively narrow size distribution, having spherical shape, a controlled mean size between 7 and 70 nm and high colloidal stability. The formed NPs can also be of importance for catalytic and biomedical applications.
  • Публикация
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    Ex vivo biodistribution of gallium-68-labeled porous silicon nanoparticles
    (2020) Tishchenko, V. K.; Mikhailovskaya, A. A.; Smoryzanova, O. A.; Petriev, V. M.; Kabashin, A. V.; Zavestovskaya, I. N.; Кабашин, Андрей Викторович; Завестовская, Ирина Николаевна
    © Published under licence by IOP Publishing Ltd.The introduction of nanotechnology in nuclear imaging has gained significant interest and could have promising potential for clinical use. Tumor imaging with radiolabeled nanoparticles (NPs) may be used for early detection, characterization, staging of disease, and for monitoring treatment efficacy. In this study we evaluated the biodistribution of porous silicon NPs labeled with positron-emitter gallium-68 in Wistar rats with subcutaneously transplanted cholangioma RS-1. The uptake of 68Ga-NPs in tumor tissue was 0.240.02 %ID/g at 5 min postinjection (p.i.) and climbed to 0.870.07 %ID/g at 5 h p.i. On the other hand, the amount of free 68Ga injected as 68GaCl3 solution decreased from 0.340.07 %ID/g at 5 min p.i. to 0.070.01 %ID/g at 5 h p.i. The highest level of radioactivity revealed in liver (8.27-15.79 %ID/g), spleen (0.98-1.27 %ID/g), and lungs (0.98-1.80 %ID/g). 68Ga-NPs were also determined in blood: up to 3.330.14 %ID/g at 5 min p.i. The uptake of 68Ga-NPs in other organs and tissues didn't exceed 1 %ID/g. In conclusion, the obtained results suggest that 68Ga-NPs could be suitable for use as molecular imaging probes.