Yulia Bezsudnova scite author profile

Silicon nanoparticles (SiNPs) prepared by mechanical grinding of luminescent porous silicon were coated with a biopolymer (dextran) and investigated as a potential theranostic agent for bioimaging and sonodynamic therapy. Transmission electron microscopy, photoluminescence and Raman scattering measurements of dextran-coated SiNPs gave evidence of their enhanced stability in water. In vitro experiments confirmed the lower cytotoxicity of the dextran-coated NPs in comparison with uncoated ones, especially for high concentrations of about 2 mg ml−1. Efficient uptake of the NPs by cancer cells was found using bioimaging in the optical transmittance and photoluminescence modes. Treatment of the cells with uptaken SiNPs by therapeutic ultrasound for 5–20 min resulted in a strong decrease in the number of living cells, while the total number of cells remained nearly unchanged. The obtained data indicate a ‘mild’ effect of the combined action of ultrasonic irradiation and SiNPs on cancer cells. The observed results reveal new opportunities for controlling the photoluminescent and sonosensitizing properties of silicon-based NPs for applications in the diagnostics and mild therapy of cancer.

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Detection of human auditory evoked brain signals with a resilient nonlinear optically pumped magnetometer

Kowalczyk

Bezsudnova

Jensen

et al. 2021

NeuroImage

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Highlights We have built and tested an Optically Pumped Magnetometer based on non-linear magnetooptical rotation. We present a new approach to OPM- based MEG using a modular NOPM sensor. Our sensor is resilient to non-zero and non-uniform magnetic field environments and crosstalk free. We demonstrate the operation of the NOPM sensor by measuring auditory response and calculating time-frequency representation of power.

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Controlled energy deposition and void-like modification inside transparent solids by two-color tightly focused femtosecond laser pulses

Potemkin

Mareev

Bezsudnova

et al. 2017

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We report a bulk void-like micromodification of fused silica using two-color μJ-energy level tightly focused (NA = 0.5) co-propagating seeding (visible, 0.62 μm) and heating (near-IR, 1.24 μm) femtosecond laser pulses with online third harmonic diagnostics of created microplasmas as well as subsequent laser-induced void-like defects. It has been shown experimentally and theoretically that production of seeding electrons through multiphoton ionization by visible laser pulses paves the way for controllability of the energy deposition and laser-induced micromodification via carrier heating by delayed infrared laser pulses inside the material. Experimental results demonstrate wide possibilities to increase the density of energy deposited up to 6 kJ cm−3 inside the dielectric by tight focusing of two color fs-laser pulses and elliptical polarization for infrared heating fs-laser pulses. The developed theoretical approach predicts the enhancement of deposited energy density up to 9 kJ cm−3 using longer (mid-IR) wavelengths for heating laser pulses.

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Biodegradation model of porous silicon nanoparticles

Gongalsky

Sviridov

Bezsudnova

et al. 2020

Colloids and Surfaces B: Biointerfaces

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