Collection of scientific works Nanosystems, nanomaterials, nanotechnologies
Year 2025 Volume 23, Issue 3
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P. P. HORBYK, S. M. MAKHNO, A. P. KUSYAK, R. V. MAZURENKO, O. M. LISOVA, S. L. PROKOPENKO, I. V. DUBROVIN, S. P. TURANS'KA, A. L. PETRANOVS'KA, and O. M. SHCHEHLOV

O. O. Chuiko Institute of Surface Chemistry of the NAS of Ukraine, 17 Olega Mudraka Str., UA-03164 Kyiv, Ukraine

Polyfunctional Magnetosensitive Nanostructures and Materials: State-of-the-Art and Research Prospects

927–963 (2025)

PACS numbers: 68.37.Lp, 75.50.Tt, 75.60.-d, 75.75.Cd, 81.70.Pg, 82.30.Lp, 87.19.xj, 87.85.Rs

Received 6 February, 2025

The results of the authors' research within the new interdisciplinary scientific and practical direction 'Polyfunctional magnetically sensitive nanostructures and materials', covering a wide range of topical modern problems of chemistry, physics, medicine (including oncology), photopharmacology, biology, ecology, engineering, etc. are analysed and summarized. Achievements are summarized, and directions of development of scientific approach in the field of creation of the molecular and nanoscale objects with predefined properties are analysed. Examples of promising developments for practical use related to the chemical design of multilevel core–shell nanocomposites with the functions of biomedical nanorobots, which can move independently along different trajectories, be controlled by external fields, and interact with objects and the environment, are considered. The article presents the creation of a new generation of magnetic adsorbents with different surface properties for medical, technical, and environmental purposes, the development of a nanotechnological basis for non-invasive photopharmacological methods of anticancer therapy, and controlled pharmacological effects of a given direction on biological cellular systems. Considerable attention is paid to the synthesis of new magnetic fluids based on saline solution containing magnetically sensitive multilevel polyfunctional nanocomposites, which allow the transportation and retention of nanoscale magnetically sensitive drug carriers in the vessels of various types of the circulatory system using an external magnetic field, with topical anticancer drugs and antibodies. The prospect of new effective protective materials capable of absorbing electromagnetic (EM) radiation in specific ranges of the electromagnetic spectrum for use in high-tech electronics and protection against electromagnetic pollution, the creation of scientific foundations of protective coatings active in the infrared (IR) and ultrahigh frequency (UHF) ranges of the spectrum, are shown. The advantages of protective materials containing magnetic, dielectric and electrically conducting components, and core–shell nanocomposites include reduction of reflection coefficients, optimization of loss and impedance coherence with open space, and wideband absorption. These important factors determining the serviceability of the materials, as well as general technical factors such as mass–dimensional characteristics and corrosion resistance, and point to the prospects for unique technical applications, particularly in the field of creating new types of surfaces and coatings with defined electrodynamic properties.

KEY WORDS: nanostructure, core–shell nanocomposite, functions of nanorobot, magnetic adsorbent, magnetic fluid, interaction with electromagnetic radiation, antitumor therapy, photopharmacology

DOI: https://doi.org/10.15407/nnn.23.03.0927

Citation:
P. P. Horbyk, S. M. Makhno, A. P. Kusyak, R. V. Mazurenko, O. M. Lisova, S. L. Prokopenko, I. V. Dubrovin, S. P. Turans'ka, A. L. Petranovs'ka, and O. M. Shchehlov, Polyfunctional Magnetosensitive Nanostructures and Materials: State-of-the-Art and Research Prospects, Nanosistemi, Nanomateriali, Nanotehnologii, 23, No. 3: 927–963 (2025); https://doi.org/10.15407/nnn.23.03.0927
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