Designing a New Anti Microbe and Virus Volleyball Ball

Document Type : Original research papers

Authors

1 Department of Physical Education and Sport Science, Faculty of Educational Science and Psychology, University of Mohaghegh Ardabili, Ardabil, Iran

2 Department of Physical Education and Sport Sciences, Faculty of Educational Sciences and Psychology, University of Mohaghegh Ardabili, Ardebil, Iran

3 Dept. of Sport Physiology, Faculty of Physical Education and Sport Sciences, University of Birjand, Birjand, Iran.

4 Department of Physical Education and Sport Sciences, Payam Noor University, Tehran, Iran

Abstract

Ball sports are used for various purposes among athletes. Volleyball is one of the most popular sports which very limited during the outbreak of Corona virus. Therefore, the purpose of this study was to design a new anti microb and virus Volleyball ball. The present study was done in order to design and manufacture new Volleyball ball to prevent microbes and virus distribution among Volleyball athletes. Initially, in order to design and produce a new antimicrobial Volleyball ball to prevent germs and viruses among Volleyball athletes, using rubber, it was combined with the material of sports balls such as titanium oxide, paraffin, and etc in the Nider machine. The obtained rubber material was transferred to the rubber baking machine for making the first layer of the ball. Then, in order to maintain the spherical shape of the first layer of the new Volleyball ball, we covered it with thread. To form the third layer of the new ball and to increase its bounce, a special fabric was used instead of rubber. Finally, we used special leather foam to form the last layer of the new ball. In the latex machine, we covered it twice with glue in order to better adhesion of the foam to the third layer. For the first time in the ball industry, this study investigated the antimicrobial ability of nano-silver against microorganisms .Based on previous research that examined the antimicrobial properties of nano-silver against microbes in various industries , it can be suggested that the use of nano-silver in the ball industry could be useful in eradicating a variety of microbes and viruses.

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  1. Bahr R, Reeser JC. Injuries among world-class professional beach volleyball players: the Federation Internationale de Volleyball beach volleyball injury study. The American journal of sports medicine. 2003;31(1):119-25.
  2. Kumar S, Nyodu R, Maurya VK, Saxena SK. Morphology, genome organization, replication, and pathogenesis of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Coronavirus Disease 2019 (COVID-19). 2020:23.
  3. Hughes D, Saw R, Perera NKP, Mooney M, Wallett A, Cooke J, et al. The Australian Institute of Sport framework for rebooting sport in a COVID-19 environment. Journal of Science and Medicine in Sport. 2020;23(7):639-63.
  4. Baggish A, Drezner JA, Kim J, Martinez M, Prutkin JM. Resurgence of sport in the wake of COVID-19: cardiac considerations in competitive athletes. BMJ Publishing Group Ltd and British Association of Sport and Exercise Medicine; 2020.
  5. Mollick MMR, Bhowmick B, Maity D, Mondal D, Bain MK, Bankura K, et al. Green synthesis of silver nanoparticles using Paederia foetida L. leaf extract and assessment of their antimicrobial activities. International Journal of Green Nanotechnology. 2012;4(3):230-9.
  6. Brito SdC, Bresolin JD, Sivieri K, Ferreira MD. Low-density polyethylene films incorporated with silver nanoparticles to promote antimicrobial efficiency in food packaging. Food Science and Technology International. 2020;26(4):353-66.
  7. Descendant, Hadith, Nia H. Investigation of antibacterial activity of silver nanoparticles synthesized from fruit extract of Scrophularia striata. Cell and Tissue. 2017; 8 (2): 206-13.
  8. Chook SW, Chia CH, Zakaria S, Ayob MK, Chee KL, Huang NM, et al. Antibacterial performance of Ag nanoparticles and AgGO nanocomposites prepared via rapid microwave-assisted synthesis method. Nanoscale research letters. 2012;7(1):1-7.
  9. Zapata PA, Tamayo L, Páez M, Cerda E, Azócar I, Rabagliati FM. Nanocomposites based on polyethylene and nanosilver particles produced by metallocenic “in situ” polymerization: synthesis, characterization, and antimicrobial behavior. European Polymer Journal. 2011;47(8):1541-9.
  10. Aqleh R., Babak, Ghasemi, Muhaddith, Zamani, Hojjatullah. Inactivation of Rhabdovirus carpio virus (spring carp virus) using silver nanoparticles in EPC cells. Scientific Journal of Aquatic Physiology and Biotechnology. 2017; 4 (4): 13-28
  11. Cabore JW, Karamagi HC, Kipruto H, Asamani JA, Droti B, Seydi ABW, et al. The potential effects of widespread community transmission of SARS-CoV-2 infection in the World Health Organization African Region: a predictive model. BMJ global health. 2020;5(5):e002647.
  12. Ratten V. Coronavirus (covid-19) and entrepreneurship: changing life and work landscape. Journal of Small Business & Entrepreneurship. 2020;32(5):503-16.
  13. Hammami A, Harrabi B, Mohr M, Krustrup P. Physical activity and coronavirus disease 2019 (COVID-19): specific recommendations for home-based physical training. Managing Sport and Leisure. 2020:1-6.
  14. Hillermeier R, Hasson T, Friedrich L, Ball C. Advanced thermosetting resin matrix technology for next generation high volume manufacture of automotive composite structures. SAE Tech Pap Ser. 2013;1:1-5.
  15. Chappelet J-L, Kübler-Mabbott B. Introduction: Chapter taken from The International Olympic Committee and the Olympic System: The Governance of World Sport ISBN: 978-0-415-43167-5. Routledge Online Studies on the Olympic and Paralympic Games. 2012;1(28):1-4.
  16. Chappelet J-L, Kübler-Mabbott B. Chapter 7-The regulators: Chapter taken from The International Olympic Committee and the Olympic System: The Governance of World Sport ISBN: 978-0-415-43167-5. Routledge Online Studies on the Olympic and Paralympic Games. 2012;1(28):128-73.
  17. Song H, Ko K, Oh L, Lee B. Fabrication of silver nanoparticles and their antimicrobial mechanisms. Eur Cells Mater. 2006;11(Suppl 1):58.
  18. Cho K-H, Park J-E, Osaka T, Park S-G. The study of antimicrobial activity and preservative effects of nanosilver ingredient. Electrochimica Acta. 2005;51(5):956-60.
  19. Li L, Zhao C, Zhang Y, Yao J, Yang W, Hu Q, et al. Effect of stable antimicrobial nano-silver packaging on inhibiting mildew and in storage of rice. Food chemistry. 2017;215:477-82.
  20. Deng X, Nikiforov AY, Coenye T, Cools P, Aziz G, Morent R, et al. Antimicrobial nano-silver non-woven polyethylene terephthalate fabric via an atmospheric pressure plasma deposition process. Scientific reports. 2015;5(1):1-10.
  21. .
  22. Mirzababa H., Hamed, Montazer, Rahimi, Karim M. Investigation of antimicrobial effect of nylon flooring containing nano-silver. Quarterly Journal of Medical Sciences, Islamic Azad University, Tehran Medical Branch. 2011; 21 (2): 101-7Rezić I, Haramina T, Rezić T. Metal nanoparticles and carbon nanotubes—perfect antimicrobial nano-fillers in polymer-based food packaging materials. food packaging: Elsevier; 2017. p. 497-532.
  23. Fatahian R, Noori M, Khajavi R. Exrtaction of sericin from degumming process of silk fibres and its application on nonwoven fabrics. Int J Adv Chem. 2017;5:25-8.
  24. Fara, Elias, Mohammadi, Imani, Narchin, Parvaneh. Improving the antibacterial properties of toilet paper using silver nanoparticles. Wood and forest science and technology research. 2015; 22 (2): 119-36.
  25. Simon D. Alicia Culver (Responsible Purchasing Network) Chris Geiger, Ph. D.(Department of the Environment).
  26. Hong X, Wen J, Xiong X, Hu Y. Shape effect on the antibacterial activity of silver nanoparticles synthesized via a microwave-assisted method. Environmental science and pollution research. 2016;23(5):4489-97.
  27. Li M, Pan Y, Zou Y, editors. Application and Optimization Design of Titanium Alloy in Sports Equipment. Journal of Physics: Conference Series; 2021: IOP Publishing.
  28. Wu P, Xie R, Imlay JA, Shang JK. Visible-light-induced photocatalytic inactivation of bacteria by composite photocatalysts of palladium oxide and nitrogen-doped titanium oxide. Applied Catalysis B: Environmental. 2009;88(3-4):576-81.
  29. Sotiriou GA, Pratsinis SE. Engineering nanosilver as an antibacterial, biosensor and bioimaging material. Current opinion in chemical engineering. 2011;1(1):3-10.
  30. Deshmukh SP, Patil S, Mullani S, Delekar S. Silver nanoparticles as an effective disinfectant: A review. Materials Science and Engineering: C. 2019;97:954-65.
  31. Ahmadi S. The importance of silver nanoparticles in human life. Advances in Applied NanoBio-Technologies. 2020;1(1):5-9.
  32. Das CA, Kumar VG, Dhas TS, Karthick V, Govindaraju K, Joselin JM, et al. Antibacterial activity of silver nanoparticles (biosynthesis): A short review on recent advances. Biocatalysis and Agricultural Biotechnology. 2020;27:101593.
  33. Prema P, Thangapandiyan S, Immanuel G. CMC stabilized nano silver synthesis, characterization and its antibacterial and synergistic effect with broad spectrum antibiotics. Carbohydrate polymers. 2017;158:141-8.