Synthesis and comparative characteristics of biological activities of (La, Sr)MnO3 and Fe3O4 nanoparticles

Olga Shydlovska; Nadiya Zholobak; Svitlana Dybkova; Sergej Osinsky; Larissa Bubnovskaya; Oleksandr Yelenich; Sergii Solopan; Anatolii Belous

doi:10.1515/ejnm-2016-0028

Artikel

Synthesis and comparative characteristics of biological activities of (La, Sr)MnO₃ and Fe₃O₄ nanoparticles

Olga Shydlovska
Olga Shydlovska is a PhD student at the National Academy of Sciencess (NAS) of Ukraine. Her areas of research include: biological properties, in particular, antiviral and antioxidant properties nanoparticles of different metals or their oxides, such as gold nanoparticles, iron oxide and cerium dioxide nanoparticles.
, Nadiya Zholobak
Nadiya Zholobak is a senior researcher with the Candidates of Sciences (PhD Biology). Her areas of research include: nanobiotechnology and antiviral substances search, studying of their effects in vitro and in vivo and nanotherapy of viral infections. She has published more than 100 scientific papers and has 26 patents in the Ukraine.
, Svitlana Dybkova
Svitlana Dybkova is a senior researcher with the Candidates of Sciences (PhD Biology). Her areas of research include: nanobiotechnology, nanomedicine, nanotoxicology and mechanisms of metal nanoparticles influence on prokaryotic cells, eukaryotic in vitro (normal and cancer) cells and in vivo. She has published 120 scientific papers and has eight patents in the Ukraine.
, Sergej Osinsky
Sergej Osinsky is a DMedSc. His areas of research include: tumor pathophysiology, in particular metabolic microenvironment (tumor pH, oxygenation, perfusion, energy status; modifying agents of cancer therapy, hypoxic radiosensitizers; hypoxia-associated molecular profile of tumors, in particular human gastric and pancreatic cancers, and its effect on malignant progression, its correlation with minimal residual disease. His other scientific interests include methods of nanohyperthermia of malignant tumors using ferromagnetic materials as inductors and creation of pH- and thermosensitive magnetic nanocomposites with immobilized cytostatics and/or proteins for selective antitumor therapy.
, Larissa Bubnovskaya
Larissa Bubnovskaya is a senior researcher with the candidates of Sciences (PhD, Biology). Her areas of research include: biochemical basis of the tumor pathophysiology, in particular tumor pH, oxygenation, perfusion, energy status (study with microelectrode technique, NMR spectroscopy, biochemical methods), and working out the anticancer as well as modifying agents of cancer therapy (local microwave hyperthermia induced hyperglycemia and hypoxic radiosensitizers), hypoxia-associated molecular and phospholipid profiles of human gastric cancer. Her other areas of research include the investigation of the biological activity of ferromagnetic materials in particular MFs in experiments in vivo.
, Oleksandr Yelenich
Oleksandr Yelenich is a researcher with the Candidates of Sciences (PhD, Chemistry) at the V.I. Vernadsky Institute of General and Inorganic Chemistry, NAS of Ukraine, Kiyv, Ukraine. His areas of research include: studying the peculiarities of the synthesis and properties of ferrimagnetic nanoparticles with spinel structure and the synthesis and studying of functionalized magnetic homo- and heterostructures based on ferrite nanoparticles for advanced technical and biomedical applications.
, Sergii Solopan
Sergii Solopan is a senior researcher with the Candidate of Sciences (PhD, Chemistry). His areas of research included: nanosized Pb- and Sn-containing compounds with perovskite structure, synthesis and studying of ferromagnetic nanoparticles with spinel and perovskite structure.
und Anatolii Belous
Anatolii Belous is a Professor, and Head of the Department of Solid State Chemistry. He graduated from the Kiev Polytechnic Institute, in the Radio Electronic Faculty in 1974. After that, he was a graduate student in the Karpov Physico-Chemistry Research Institute, Moscow and at the V.I. Vernadsky Institute of General and Inorganic Chemistry, NAS of Ukraine, Kiev, Ukraine. His areas of research include: the development of lithium-conducting solid electrolytes, microwave dielectrics, ferroelectrics type semiconductor and nanoscale ferromagnetic systems.

Veröffentlicht/Copyright: 22. März 2017

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Aus der Zeitschrift European Journal of Nanomedicine Band 9 Heft 1

Abstract

In the last decade, ferromagnetic nanoparticles that are able to be heated under an AMF (alternating magnetic field) have gained considerable interest in the field of nanotechnology. The current study explores the peculiarity of the synthesis and the properties of Fe₃O₄ and (La, Sr)MnO₃ nanoparticles by cryochemical and sol-gel technology, as well the comparative analysis of biological activities of synthesized nanoparticles on different cell lines: the ST cell line (diploid epithelial swine testicular cell line) and the MCF-7S cell line (human breast cancer line). In the study, Fe₃O₄ and (La, Sr)MnO₃ nanoparticles with superparamagnetic properties were synthesized, and magnetic fluids based on them that were efficiently heated when subjected to an AMF (specific loss power ~33–37 W/g) were prepared. It was observed that the temperature of magnetic fluids based on Fe₃O₄ nanoparticles increases linearly to the time of the AMF exposition, whereas for (La, Sr)MnO₃-based fluid, it stabilizes within a given temperature range. It was shown that the nanoparticles of (La, Sr)MnO₃, unlike Fe₃O₄, are characterized by low toxicity, antioxidant activity and the ability to influence on cell-virus interaction on normal cell lines (ST cell line). The possibility of the magnetic fluids obtained in this work to generate heat under the AMF exposition and the lack of side effects make them a potential means for magnetic hyperthermia.

Keywords: antiviral activity; ferromagnetic nanoparticles; genotoxicity; hyperthermia; magnetic fluid

About the authors

Olga Shydlovska

Olga Shydlovska is a PhD student at the National Academy of Sciencess (NAS) of Ukraine. Her areas of research include: biological properties, in particular, antiviral and antioxidant properties nanoparticles of different metals or their oxides, such as gold nanoparticles, iron oxide and cerium dioxide nanoparticles.

Nadiya Zholobak

Nadiya Zholobak is a senior researcher with the Candidates of Sciences (PhD Biology). Her areas of research include: nanobiotechnology and antiviral substances search, studying of their effects in vitro and in vivo and nanotherapy of viral infections. She has published more than 100 scientific papers and has 26 patents in the Ukraine.

Svitlana Dybkova

Svitlana Dybkova is a senior researcher with the Candidates of Sciences (PhD Biology). Her areas of research include: nanobiotechnology, nanomedicine, nanotoxicology and mechanisms of metal nanoparticles influence on prokaryotic cells, eukaryotic in vitro (normal and cancer) cells and in vivo. She has published 120 scientific papers and has eight patents in the Ukraine.

Sergej Osinsky

Sergej Osinsky is a DMedSc. His areas of research include: tumor pathophysiology, in particular metabolic microenvironment (tumor pH, oxygenation, perfusion, energy status; modifying agents of cancer therapy, hypoxic radiosensitizers; hypoxia-associated molecular profile of tumors, in particular human gastric and pancreatic cancers, and its effect on malignant progression, its correlation with minimal residual disease. His other scientific interests include methods of nanohyperthermia of malignant tumors using ferromagnetic materials as inductors and creation of pH- and thermosensitive magnetic nanocomposites with immobilized cytostatics and/or proteins for selective antitumor therapy.

Larissa Bubnovskaya

Larissa Bubnovskaya is a senior researcher with the candidates of Sciences (PhD, Biology). Her areas of research include: biochemical basis of the tumor pathophysiology, in particular tumor pH, oxygenation, perfusion, energy status (study with microelectrode technique, NMR spectroscopy, biochemical methods), and working out the anticancer as well as modifying agents of cancer therapy (local microwave hyperthermia induced hyperglycemia and hypoxic radiosensitizers), hypoxia-associated molecular and phospholipid profiles of human gastric cancer. Her other areas of research include the investigation of the biological activity of ferromagnetic materials in particular MFs in experiments in vivo.

Oleksandr Yelenich

Oleksandr Yelenich is a researcher with the Candidates of Sciences (PhD, Chemistry) at the V.I. Vernadsky Institute of General and Inorganic Chemistry, NAS of Ukraine, Kiyv, Ukraine. His areas of research include: studying the peculiarities of the synthesis and properties of ferrimagnetic nanoparticles with spinel structure and the synthesis and studying of functionalized magnetic homo- and heterostructures based on ferrite nanoparticles for advanced technical and biomedical applications.

Sergii Solopan

Sergii Solopan is a senior researcher with the Candidate of Sciences (PhD, Chemistry). His areas of research included: nanosized Pb- and Sn-containing compounds with perovskite structure, synthesis and studying of ferromagnetic nanoparticles with spinel and perovskite structure.

Anatolii Belous

Anatolii Belous is a Professor, and Head of the Department of Solid State Chemistry. He graduated from the Kiev Polytechnic Institute, in the Radio Electronic Faculty in 1974. After that, he was a graduate student in the Karpov Physico-Chemistry Research Institute, Moscow and at the V.I. Vernadsky Institute of General and Inorganic Chemistry, NAS of Ukraine, Kiev, Ukraine. His areas of research include: the development of lithium-conducting solid electrolytes, microwave dielectrics, ferroelectrics type semiconductor and nanoscale ferromagnetic systems.

Conflict of interest statement: Authors state no conflict of interest. All authors have read the journal’s publication ethics and publication malpractice statement available at the journal’s website and hereby confirm that they comply with all its parts applicable to the present scientific work.

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Received: 2016-10-11

Accepted: 2017-1-23

Published Online: 2017-3-22

Published in Print: 2017-1-1

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Artikel in diesem Heft

https://doi.org/10.1515/ejnm-2016-0028

Schlagwörter für diesen Artikel

antiviral activity; ferromagnetic nanoparticles; genotoxicity; hyperthermia; magnetic fluid