Effect of silver nanoparticles on antibiotic resistance of microorganisms in the treatment of endometritis in cows

   The main etiological factor in endometritis is pathogenic and opportunistic pathogenic microflora entering the uterus during the postpartum period, during estrus, artificial insemination with contaminated sperm. A study was carried out to investigate changes in antibacterial sensitivity of microorganisms during therapy after labor purulent-catarrhal endometritis of cows with a preparation containing silver nanoparticles. To study the role of opportunistic pathogenic microflora in the etiology of postpartum purulent-catarrhal endometritis a clinical study of 150 cows in a farm in the Novosibirsk region during mass calving was carried out. Animals were divided into experimental and control groups according to the analogy principle. The control group received fish oil intramuscularly in a dose of 150 ml with oxytetracycline hydrochloride in a dose of 40 mg/kg of live weight once every 48 hours and uteroton intramuscularly in a dose of 10 ml once every 48 hours. The experimental group received intrauterine injections of argovit 10 % aqueous solution at a dose of 100 ml once every 48 h and uteroton intramuscularly at a dose of 10 ml once every 48 h. It was found that the treatment of postpartum purulent-catarrhal endometritis of cows with argovit decreased the average duration of treatment of the disease by 1.8 times compared to the preparation in the control group. When treating postpartum purulent-catarrhal endometritis of cows with argovit, an increase in antibiotic sensitivity of the isolated microflora to 21 drugs (87.5 %) from 1.2 to 100% was found. In the control group, there was a decrease in antibiotic sensitivity of the isolated microflora to 18 (75 %) preparations from - 1.1 to 28.7 %.

1. Madoz L. V., Giuliodori M. J., Migliorisi A. L., Jaureguiberry M., Sota R. L. Endometrial cytology, biopsy, and bacteriology for the diagnosis of subclinical endometritis in grazing dairy cows // Journal of Dairy Science. 2014. Vol. 97. N 1. P. 195–201.

2. Wang J. Comparison of vaginal microbial community structure in healthy and endometritis dairy cows by PCR-DGGE and real-time PCR // Anaerobe. 2016. Vol. 38. P. 1–6.

3. Коба И. С. Распространение острых и хронических эндометритов у коров в сельскохозяйственных организациях Краснодарского края / И. С. Коба, М. Б. Решетка, М. С. Дубовиков // Вестник Алтайского государственного аграрного университета. – 2016. – Т. 2. – № 136. – С. 103–106.

4. Баймишев М. Х. К этиологии послеродовых осложнений у коров черно-пестрой породы / М. Х. Баймишев, В. С. Григорьев // Известия Омского государственного аграрного университета. – 2009. – Т. 22. – № 2. – С. 267–269.

5. Медведев Г. Ф. Причины, диагностика, лечение и профилактика метритного комплекса / Г. Ф. Медведев, Н. Гавриченко // Ветеринарное дело. – 2013. – № 10. – С. 37–40.

6. Валюшкин К. Д. Ветеринарное акушерство, гинекология и биотехнология размножения: монография / К. Д. Валюшкин. – М.: Колос, 2003. – 495 с.

7. Терентьева Н. Ю. Роль микроорганизмов в этиологии акушерских заболеваний коров / Н. Ю. Терентьева, В. А. Ермолаев // Вестник Ульяновской государственной сельскохозяйственной академии. – 2015. – Т. 4. – № 32. – С. 147–155.

8. D'Costa V. M., McGrann K. M., Hughes D. W. Sampling the antibiotic resistome // Science. 2006. Р. 374–377. DOI: 10.1126/science.1120800.

9. Шкиль Н. Н. Влияние антибиотиков и наночастиц серебра на изменение чувствительности E. coli к антибактериальным препаратам / Н. Н. Шкиль, Е. В. Нефедова // Сибирский вестник сельскохозяйственной науки. – 2020. – Т. 50. – № 2. – С. 84–91.

10. Naqvi S. Z., Kiran U., Ali M. I., Jamal A., Hameed A., Ahmed S., Ali N. Combined efficacy of biologically synthesized silver nanoparticles and different antibiotics against multidrug-resistant bacteria // International Journal of Nanomedicine. 2013. Vol. 8. P. 3187–3195. DOI: 10.2147/IJN.S49284.

11. Mohamed M. S. M., Mostafa H. M., Mohamed S. H. Combination of silver nanoparticles and vancomycin to overcome antibiotic resistance in planktonic/biofilm cell from clinical and animal source // Microbial Drug Resistance. 2020. Nov. 26 (11). P. 1410–1420. DOI: 10.1089/mdr.2020.0089.

12. Singh R., Wagh P., Wadhwani S., Gaidhani S., Kumbhar A., Bellare J., Ananda Chopade B. Synthesis, optimization, and characterization of silver nanoparticles from Acinetobacter calcoaceticus and their enhanced antibacterial activity when combined with antibiotics // International Journal of Nanomedicine. 2013. Vol. 8. P. 4277–4290. DOI: 10.2147/IJN.S48913.

13. Panpaliya N. P., Dahake P. T., Kale Y. J., Dadpe M. V., Kendre S. B. In vitro evaluation of antimicrobial property of silver nanoparticles and chlorhexidine against five different oral pathogenic bacteria // Saudi Dental Journal. 2019. N 31 (1). P. 76–83. DOI: 10.1016/j.sdentj.2018.10.004.

14. Smekalova M., Aragon V., Panacek A., Prucek R., Zboril R., Kvitek L. Enhanced antibacterial effect of antibiotics in combination with silver nanoparticles against animal pathogens // Journal of Veterinary. 2016. Vol. 209. P. 174–179. DOI: 10.1016/j.tvjl.2015.10.032.

15. Shkil N. N., Nefyodova E. V., Shkil N. A., Nozdrin G. A., Lazareva M. V., Rasputina O. V., Ryumkina I. N. Adjuvant properties of silver and dimethyl sulfoxide nanoparticles in studying antibacterial activity of antibiotics against E. coli // International journal of agriculture and biological science. 2020. Vol. 4. P. 119–126. DOI: 10.5281/zenodo.4286955.