In-Vitro antibacterial activity of glass ionomer cements containing silver nanoparticles synthesized from leaf extract of Mentha piperita
DOI:
https://doi.org/10.5195/d3000.2022.267Parole chiave:
Antibacterial activity, Glass ionomer cement, Mentha piperita, Silver nanoparticlesAbstract
Purpose: The aim of this study was to evaluate the antibacterial activity of glass ionomer cement incorporated with silver nanoparticles (AgNPs) synthetized using mint leaf extract (Mentha piperita, M. piperita) on some oral cavity bacteria.
Materials and methods: In the present study, M. piperita leaf extract was used for the synthesis of AgNPs. A total of 60 glass ionomer cement (GIC) disk-shaped specimens were prepared and divided into two groups: conventional GIC (C-GIC), and glass ionomer cement with 2 wt% AgNPs (GIC-AGNPs). The antibacterial activity of the GIC specimens in comparison with Ampicillin disk (10 µg/ml) was investigated against Streptococcus mutans, Enterococcus faecalis, Lactobacillus acidophilus, Lactobacillus casei, and Streptococcus aureus by measuring the diameter of growth inhibition zones.
Results: C-GIC specimens failed to show any antibacterial effect against the studied bacteria. However, the GIC-AgNPs had relatively significant antibacterial effects on S. mutans, L. acidophilus, L. casei and S. aureus. The highest antibacterial effect of GIC-AgNPs specimens was reported against L. acidophilus (P <0.001). GIC-AgNPs had no antibacterial effect on E. faecalis.
Conclusion: Glass ionomer cement incorporated with AgNPs synthetized using M. piperita showed a promising antibacterial effect against oral cariogenic pathogens.
Riferimenti bibliografici
American Association of Orthodontists. 2018. AAO Economics of Orthodontists/Patient Census survey comparison results [Internet]. American Association of Orthodontists;St. Louis, MO: Available from: https://assets-prod-www1.aaoinfo.org/assets-prod-www1/2019/02/14152041/2012-2016-Comparison-Data.pdf. cited 2018 May 17.
Do malocclusion and orthodontic treatment impact oral health? A systematic review and meta-analysis. American Journal of Orthodontics and Dentofacial Orthopedics. Macey R, Thiruvenkatachari B, O'Brien K, Batista KB. 2020 Jun 1;157(6):738-44.
Incidence of caries lesions among patients treated with comprehensive orthodontics. American Journal of Orthodontics and Dentofacial Orthopedics. Richter AE, Arruda AO, Peters MC, Sohn W. 2011 May 1;139(5):657-64.
Linking orthodontic treatment and caries management for high-risk adolescents. American Journal of Orthodontics and Dentofacial Orthopedics. Cruz CL, Edelstein BL. 2016 Apr 1;149(4):441-2.
Effect of orthodontic band placement on the chemical composition of human incisor tooth plaque. Archives of oral biology. Chatterjee R, Kleinberg I. 1979 Jan 1;24(2):97-100.
Initial changes of dental plaque, gingivitis and decalcification in Korean orthodontic patients with fixed appliance. The korean journal of orthodontics. Kang KJ, Shon BH. 1999;29(3):361-74.
The effect of fixed orthodontic appliances on the oral carriage of Candida species and Enterobacteriaceae. The European Journal of Orthodontics. Hägg U, Kaveewatcharanont P, Samaranayake YH, Samaranayake LP. 2004 Dec 1;26(6):623-9.
Comparison of oral microbiota in orthodontic patients and healthy individuals. Microbial pathogenesis. Sun F, Ahmed A, Wang L, Dong M, Niu W. 2018 Oct 1;123:473-7.
Critical evaluation of incidence and prevalence of white spot lesions during fixed orthodontic appliance treatment: A meta-analysis. Journal of International Society of Preventive & Community Dentistry. Sundararaj D, Venkatachalapathy S, Tandon A, Pereira A. 2015 Nov;5(6):433.
The effect of orthodontic treatment on plaque and gingivitis. American Journal of Orthodontics and Dentofacial Orthopedics. Davies TM, Shaw WC, Worthington HV, Addy M, Dummer P, Kingdon A. 1991 Feb 1;99(2):155-61.
Orthodontic appliances did not increase risk of dental caries and periodontal disease under preventive protocol. The Angle Orthodontist. Bergamo AZ, de Oliveira KM, Matsumoto MA, Nascimento CD, Romano FL, da Silva RA, da Silva LA, Nelson-Filho P. 2019 Jan;89(1):25-32.
The effect of incorporation Nano Cinnamon powder on the shear bond of the orthodontic composite (an in vitro study). Journal of oral biology and craniofacial research. Yaseen SN, Taqa AA, Al-Khatib AR. 2020 Apr 1;10(2):128-34.
Antimicrobial Orthodontic Wires Coated with Silver Nanoparticles. Brazilian Archives of Biology and Technology. Gonçalves IS, Viale AB, Sormani NN, Pizzol KE, Araujo-Nobre AR, Oliveira PC, Barud HG, Antonio SG, Barud HD. 2020 Oct 26;63.
Functional coatings for orthodontic archwires—A review. Materials. Bącela J, Łabowska MB, Detyna J, Zięty A, Michalak I. 2020 Jan;13(15):3257.
Incorporation of Arginine to Commercial Orthodontic Light-Cured Resin Cements—Physical, Adhesive, and Antibacterial Properties. Materials. Geraldeli S, Maia Carvalho LD, de Souza Araújo IJ, Guarda MB, Nascimento MM, Bertolo MV, Di Nizo PT, Sinhoreti MA, McCarlie VW. 2021 Jan;14(16):4391.
Effect of nanosilver mouthwash on prevention of white spot lesions in patients undergoing fixed orthodontic treatment-a randomized double-blind clinical trial. Journal of Dental Sciences. Ali A, Ismail H, Amin K. 2021 May 1.
Applied Research Glass Ionomer Cement with TiO2 Nanoparticles in Orthodontic Treatment. Journal of Nanoscience and Nanotechnology. Ren J, Du Z, Lin J, Hirabe H, Sakai K. 2021 Feb 1;21(2):1032-41.
The effect of N-acetylcysteine on the antibacterial capability and biocompatibility of nano silver–containing orthodontic cement. The Angle Orthodontist. Ding R, Qian Y, Chen M, Yi J, Zhao Z. 2021 Feb 11.
Novel rechargeable nano-CaF2 orthodontic cement with high levels of long-term fluoride release. Journal of dentistry. Yi J, Weir MD, Melo MA, Li T, Lynch CD, Oates TW, Dai Q, Zhao Z, Xu HH. 2019 Nov 1;90:103214.
Green synthesis and characterization of Ag nanoparticles from Mangifera indica leaves for dental restoration and antibacterial applications. Progress in biomaterials. Sundeep D, Kumar TV, Rao PS, Ravikumar RV, Krishna AG. 2017 May;6(1):57-66.
Size and aging effects on antimicrobial efficiency of silver nanoparticles coated on polyamide fabrics activated by atmospheric DBD plasma. ACS applied materials & interfaces. Zille A, Fernandes MM, Francesko A, Tzanov T, Fernandes M, Oliveira FR, Almeida L, Amorim T, Carneiro N, Esteves MF, Souto AP. 2015 Jul 1;7(25):13731-44.
Pear fruit extract-assisted room-temperature biosynthesis of gold nanoplates. Colloids and Surfaces B: Biointerfaces. Ghodake GS, Deshpande NG, Lee YP, Jin E. 2010 Feb 1;75(2):584-9.
Green synthesis of silver nanoparticles toward bio and medical applications: review study. Artificial cells, nanomedicine, and biotechnology. Mousavi SM, Hashemi SA, Ghasemi Y, Atapour A, Amani AM, Savar Dashtaki A, Babapoor A, Arjmand O. 2018 Nov 12;46(sup3):S855-72.
Synthesis of silver nanoparticles using gum Arabic: Evaluation of its inhibitory action on Streptococcus mutans causing dental caries and endocarditis. Journal of Infection and Public Health. Al-Ansari MM, Al-Dahmash ND, Ranjitsingh AJ. 2021 Mar 1;14(3):324-30.
Effectiveness of Mentha piperita Leaf Extracts against Oral Pathogens: An in vitro Study. The journal of contemporary dental practice. Raghavan R, Devi MS, Varghese M, Joseph A, Madhavan SS, Sreedevi PV. 2018 Sep 1;19(9):1042-6.
Biosynthesis of silver nanoparticles using mint leaf extract (Mentha piperita) and their antibacterial activity. Advanced Science, Engineering and Medicine. Gabriela ÁM, Gabriela MD, Luis AM, Reinaldo PR, Michael HM, Rodolfo GP, Roberto VB. 2017 Nov 1;9(11):914-23.
Mentha piperita as a natural support for silver nanoparticles: A new Anti-candida albicans treatment. Colloid and Interface Science Communications. Robles-Martínez M, Patiño-Herrera R, Pérez-Vázquez FJ, Montejano-Carrizales JM, González JF, Pérez E. 2020 Mar 1;35:100253.
Antibacterial activity and physical properties of glass-ionomer cements containing antibiotics. Operative dentistry. Yesilyurt CE, Er K, Tasdemir T, Buruk K, Celik D. 2009 Jan;34(1):18-23.
Addition of chlorhexidine gluconate to a glass ionomer cement: a study on mechanical, physical and antibacterial properties. Brazilian dental journal. Marti LM, Mata MD, Ferraz-Santos B, Azevedo ER, Giro EM, Zuanon AC. 2014 Jan;25:33-7.
Use of silver nanomaterials for caries prevention: a concise review. International Journal of Nanomedicine. Yin IX, Zhao IS, Mei ML, Li Q, Yu OY, Chu CH. 2020;15:3181.
Long-term antibacterial properties and bond strength of experimental nano silver-containing orthodontic cements. Journal of Wuhan University of Technology-Mater. Sci. Ed.. Li F, Li Z, Liu G, He H. 2013 Aug 1;28(4):849-55.
The impact of silver nanoparticles integration on biofilm formation and mechanical properties of glass ionomer cement. Journal of Esthetic and Restorative Dentistry. El-Wassefy NA, Mahdy RH, El-Kholany NR. 2018 Mar;30(2):146-52.
Antibacterial orthodontic cement to combat biofilm and white spot lesions. American Journal of Orthodontics and Dentofacial Orthopedics. Wang X, Wang B, Wang Y. 2015 Dec 1;148(6):974-81.
Antibacterial properties of nano silver-containing orthodontic cements in the rat caries disease model. Journal of Wuhan University of Technology-Mater. Sci. Ed.. Li F, Fang M, Peng Y, Zhang J. 2015 Dec;30(6):1291-6.
Cytotoxic effects of silver diamine fluoride. American journal of dentistry. Fancher ME, Fournier S, Townsend J, Lallier TE. 2019 Jun 1;32(3):152-6.
Negligible particle-specific toxicity mechanism of silver nanoparticles: the role of Ag+ ion release in the cytosol. Nanomedicine: Nanotechnology, Biology and Medicine. De Matteis V, Malvindi MA, Galeone A, Brunetti V, De Luca E, Kote S, Kshirsagar P, Sabella S, Bardi G, Pompa PP. 2015 Apr 1;11(3):731-9.
The stability of silver nanoparticles in a model of pulmonary surfactant. Environmental science & technology. Leo BF, Chen S, Kyo Y, Herpoldt KL, Terrill NJ, Dunlop IE, McPhail DS, Shaffer MS, Schwander S, Gow A, Zhang J. 2013 Oct 1;47(19):11232-40.
Antimicrobial Activity of Glass Ionomer Cements with Chlorhexidine and Propolis: An In Vitro Study. Journal of Pediatric Infectious Diseases. Tuncdemir MT, Ugur AR, Ozdemir B. 2019 Jul;14(04):168-70.
Antibacterial activity of a glass ionomer containing silver nanoparticles against Streptococcus mutans and Streptococcus sanguinis. Indian Journal of Dental Research. Moshfeghi H, Haghgoo R, Sadeghi R, Niakan M, Rezvani MB. 2020 Jul 1;31(4):589.
Inhibition of microbial adherence and growth by various glass ionomers in vitro. Palenik CJ, Behnen MJ, Setcos JC, Miller CH. Dent Mater 1992;8:16-20.
Growth inhibition of glass ionomer cements on mutans streptococci. Loyola-Rodriguez JP, Garcia-Godoy F, Lindquist R. Pediatr Dent 1994;16:346-9.
Enterococcus faecalis hydrolyzes dental resin composites and adhesives. Journal of endodontics. Marashdeh MQ, Gitalis R, Levesque C, Finer Y. 2018 Apr 1;44(4):609-13.
Antimicrobial Efficacy of Mixtures of Nanosilver and Zinc Oxide Eugenol against Enterococcus faecalis. The journal of contemporary dental practice. Haghgoo R, Ahmadvand M, Nyakan M, Jafari M. 2017 Mar 1;18(3):177-81.
##submission.downloads##
Pubblicato
Fascicolo
Sezione
Licenza
Authors who publish with this journal agree to the following terms:
- The Author retains copyright in the Work, where the term “Work” shall include all digital objects that may result in subsequent electronic publication or distribution.
- Upon acceptance of the Work, the author shall grant to the Publisher the right of first publication of the Work.
- The Author shall grant to the Publisher and its agents the nonexclusive perpetual right and license to publish, archive, and make accessible the Work in whole or in part in all forms of media now or hereafter known under a Creative Commons Attribution 4.0 International License or its equivalent, which, for the avoidance of doubt, allows others to copy, distribute, and transmit the Work under the following conditions:
- Attribution—other users must attribute the Work in the manner specified by the author as indicated on the journal Web site;
- The Author is able to enter into separate, additional contractual arrangements for the nonexclusive distribution of the journal's published version of the Work (e.g., post it to an institutional repository or publish it in a book), as long as there is provided in the document an acknowledgement of its initial publication in this journal.
- Authors are permitted and encouraged to post online a prepublication manuscript (but not the Publisher’s final formatted PDF version of the Work) in institutional repositories or on their Websites prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work. Any such posting made before acceptance and publication of the Work shall be updated upon publication to include a reference to the Publisher-assigned DOI (Digital Object Identifier) and a link to the online abstract for the final published Work in the Journal.
- Upon Publisher’s request, the Author agrees to furnish promptly to Publisher, at the Author’s own expense, written evidence of the permissions, licenses, and consents for use of third-party material included within the Work, except as determined by Publisher to be covered by the principles of Fair Use.
- The Author represents and warrants that:
- the Work is the Author’s original work;
- the Author has not transferred, and will not transfer, exclusive rights in the Work to any third party;
- the Work is not pending review or under consideration by another publisher;
- the Work has not previously been published;
- the Work contains no misrepresentation or infringement of the Work or property of other authors or third parties; and
- the Work contains no libel, invasion of privacy, or other unlawful matter.
- The Author agrees to indemnify and hold Publisher harmless from Author’s breach of the representations and warranties contained in Paragraph 6 above, as well as any claim or proceeding relating to Publisher’s use and publication of any content contained in the Work, including third-party content.
Revised 7/16/2018. Revision Description: Removed outdated link.