International Conference on
Clinical Microbiology and Immunology

Biography:

The researcher has been active in the field of microbiology and using nanotechnology by making nanoparticles with a magnetic approach has taken a major step in the development of a targeted solution. During last few years, considerable research has been done in this field, and the results obtained first in the relevant university, and then continued in the private research center. Published articles as credible sources underscore the validity of this analysis. The researcher is more interested in the use of chemical-pharmaceuticals applied with nanocatalysts in bacterial culture-growth medium and has analyzed the rate of inhibition of bacterial growth, and finally the results indicate the antibacterial properties of magnetic nanoparticles. By incorporating new materials into the compound, the amount of antibacterial properties of the nanoparticles are challenged to improve the bactericidal process. According to an analysis done (by Binandeh M in Maragheh University in the Biotechnology Laboratory in 2015 year), results is well able to substantiate the results of nanoparticle performance in all respects. The continuation of this process is being studied and analyzed in a private laboratory clinic in a personal research center.

Abstract:

In most parts of the world, the topic of nanotechnology is one of the most important topics, so to develop this science, the use of magnetic nanoparticles is appropriate. A number of recent articles published by magnetic nanoparticles in the field of medicine-microbiology have investigated the mortality rate of microbes including bacteria. Bacteria have one of the simplest biological structures and are therefore easier to test. The effect of the nanoparticles on bactericidal rate is based on the nanocatalytic properties and the crystal structure, so devices such as UV Visible Spectroscopy, H¹NMR, SEM, Magnetic Detect, analyses etc. are used to record this case. In following, the data stabilize the regular structure of the nanoparticles, and can eventually be purified or combined with antibiotics in appropriate amounts in the bacterial culture medium to influence their growth process after a half-day. Bacteria can be prevented from growing or stopping completely and completely disappearing. The results of the identifiers indicate the high performance of the magnetic nanoparticles and attribute their antibacterial properties. Applying this action both in vitro and in the living environment of the body to prevent the growth of pathogenic bacteria proves to be a very safe and safe way to eliminate microbial agents from the body and the nanoparticles without any danger to the field. The magnetic is purposefully directed to out of the living cell.