Arxiv
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https://doi.org/10.36719/2707-1146/50/  41-48


Seadat Humbatova

Institute of Catalysis and Inorganic Chemistry 

named by academician of M. Nagiyev

seadet.humbatova@inbox.ru

Nizami Zeynalov 

Institute of Catalysis and Inorganic Chemistry 

named by academician of M. Nagiyev 

Doctor of Chemistry

zeynalovnizami3@gmail.com 

Elmira Aliyeva 

Institute of Catalysis and Inorganic Chemistry 

named by academician of M. Nagiyev

Ph. D. student

elmiraaliyeva84@gmail.com

Nargiz Rahimli 

Institute of Catalysis and Inorganic Chemistry 

named by academician of M. Nagiyev

narciss.rehim93@gmail.com

Dilshad Babayeva

Institute of Catalysis and Inorganic Chemistry 

named by academician of M. Nagiyev

babaevadilshad@rambler.ru


Study of the Antibacterial Activity of Levofloxacin Biocomplexes Based 

on Natural and Synthetic Polymers on Medical Meshes


Abstract

In the presented article, a model system was created and tested on cultures to determine the antibacterial activity of composites without metal nanoparticles, as well as those containing silver (Agº) and magnetite (Fe3O4) nanoparticles. During surgical operations for abdominal hernias, special antisterile synthetic meshes made of polyvinylidene fluoride were impregnated with polymer matrices, their homopolymer mixtures, and solutions with levofloxacin. The polymer- and polymer/drug-impregnated meshes were placed in bacterial media in Petri dishes, and their antibacterial activity was compared based on the diameter of the resulting lysis zones. For control purposes, levofloxacin alone was also impregnated into synthetic meshes with a size of 1 cm² and a mass of 30-40 mg, and experiments were conducted. Each synthetic mesh was impregnated with polymer samples comprising about 15-20 % of the mass, a metal oxide-metal nanoparticle coated with a polymer chain, and approximately 5 micrograms of levofloxacin. It was found that the homogeneous systems containing metal nanoparticles both levofloxacin free and the levofloxacin-loaded samples had a stronger microbial effect. This led to an increase in the area of the lysis zone. This effect is naturally related to the antibacterial properties of the metal nanoparticles themselves, which make the composite more effective in killing microbes. Additionally, compared to samples without nanoparticles, the lysis zone remains stable for a longer period.

Keywords: levofloxacin, lysis zone, magnetite, polymer, composite, nanoparticle 


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