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Original Research

Open Access

Effect of Sodium Fluoride Mouth Rinse on Elastic Properties of Elastomeric Chains

  • Barat Ali Ramazanzadeh1
  • Arezoo Jahanbin1,*,
  • Nadia Hasanzadeh1
  • Neda Eslami1

1Department of Orthodontics, Faculty of Dentistry and Dental School Research Center, Mashhad University of Medical Sciences, Mashhad, IRAN

DOI: 10.17796/jcpd.34.2.v287l152x5124142 Vol.34,Issue 2,March 2010 pp.189-192

Published: 01 March 2010

*Corresponding Author(s): Arezoo Jahanbin E-mail: Jahanbina@mums.ac.ir Dr_Arezoo_Jahanbin@yahoo.com

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Abstract

Objective: This study evaluated Sodium Fluoride mouth rinse effects on elastic properties of different elastomeric chains. Study design: In this in vitro experiment, two orthodontic chains were tested. In the first group, they were stored in artificial saliva for the entire duration, and in the second group they were immersed daily in 0.05% NaF mouth rinse for 1 minute, artificial saliva–NaF mixture for 30 minutes, and then in artificial saliva for the rest of the day. Specimens were tested at baseline, 1 hour, 24 hours, 1, 2 and 3 weeks and then the displacement of specimens to obtain 150g and 300g, also the applied force after stretching them to 100% of their original length were evaluated. Results: In contrast to force degradation,chains of both companies required more displacement to achieve both forces in the saliva- NaF mixture than saliva itself; however, the difference was only significant for the 300g force (P = 0.020). American Orthodontics chains required more displacement than Dentaurum chains to obtain both forces, also they had more load relaxation (P<0.001). Conclusions: Daily use of NaF mouth rinse does not affect force degradation and the displacement of both chains to achieve conventional orthodontic forces, but for higher force levels the displacement increase is statistically significant.

Keywords

Elastomeric chains, Force degradation, Sodium Fluoride mouth rinse

Cite and Share

Barat Ali Ramazanzadeh,Arezoo Jahanbin,Nadia Hasanzadeh,Neda Eslami. Effect of Sodium Fluoride Mouth Rinse on Elastic Properties of Elastomeric Chains. Journal of Clinical Pediatric Dentistry. 2010. 34(2);189-192.

URL:

https://www.jocpd.com/articles/10.17796/jcpd.34.2.v287l152x5124142

References

1. Fraunhofer JA, Coffelt MT, Orbel GM. The effects of artificial saliva and topical fluoride treatments on the degradation of the elastic prop-erties of orthodontic chains. Angle Orthod, 62: 265–74, 1992.

2. Baty DL, Storie DJ, Fraunhofer JA. Synthetic elastomeric chains: A lit-erature review. Am J Orthod Dentofac Orthop, 105: 536–42, 1994.

3. Santos AC, Tortamano A, Naccarato SR, Dominguez-Rodriguez GC, Vigorito JW. An in vitro comparison of the force decay generated by different commercially available elastomeric chains and NiTi closed coil springs. Braz Oral Res, 21: 51–7, 2007.

4. Stevenson JS, Kusy RP. Force application and decay characteristics of untreated and treated polyurethane elastomeric chains. Angle Orthod, 64: 455–67, 1994.

5. Huget EF, Patrick KS, Nanez LJ. Observations on the elastic behavior of a synthetic orthodontic elastomer. J Dent Res, 69: 496–501, 1990.

6. Chau Lu TZ, Wang WN, Tarng TH, Chen J. Force decay of elastomeric chains –A serial study. Part II. Am J Orthod Dentofac Orthop, 104: 373–7, 1993.

7. Ash JL, Nikolai RJ. Relaxation of orthodontic elastomeric chains and modules In Vitro and In vivo. J Dent Res, 57: 685–90, 1978.

8. Andreasen GF, Bishara ES. Comparison of alastik chains and elastics involved with intra-arch molar to molar forces. Angle Orthod, 40: 151–8, 1970.

9. Hershey G, Reynolds W. The plastic module as an orthodontic tooth moving mechanism. Am J Orthod, 67: 554–662, 1975.

10. Wong A. Orthodontic elastic materials. Angle Orthod, 46: 196–205, 1976.

11. Young J, Sandrik JL. The influence of preloading on stress relaxation of orthodontic elastic polymers. Angle Orthod, 49: 104–9, 1979.

12. Brantly W, Salander S, Myers L, Winders R. Effects of prestretching on force degradation characteristics of plastic modules. Angle Orthod, 49: 37–43, 1979.

13. Kim K, Chung C, Choy K, Lee J, Vanarsdall RL. Effects of prestretch-ing on force degradation of synthetic elastomeric chains. Am J Orthod Dentofac Orthop, 128: 477–82, 2005.

14. Storie DJ, Regennither FR, Fraunhofer JA. Characteristics of a fluo-ride-releasing elastomeric chain. Angle Orthod, 64: 199–210, 1994.

15. Wang T, Zhou G, Tan X, Dong Y. Evaluation of force degradation char-acteristics of orthodontic latex elastics In vitro and In vivo. Angle Orthod, 77: 688–93, 2007.

16. Nattrass C, Ireland AJ, Sheriff M. The effect of environmental factors on elastomeric chains and Nickel Titanium coil springs. Eur J Orthod, 20: 169–76, 1998.

17. Ferriter J, Meyers C, Lorton L. The effect of hydrogen ion concentra-tion on the force degradation rate of orthodontic polyurethane chain elastics. Am J Orthod Dentofac Orthop, 98: 404–10, 1990.

18. Gorelick L, Geiger AM, Gwinnett AJ. Incidence of white spot forma-tion after bonding and banding. Am J Orthod, 81: 93–8, 1982.

19. Thilander BL. Complications of orthodontic treatment. Curr Opin Dent, 14: 28–37, 1992.

20. Alexander SA, Ripa LW. Effects of self-applied topical fluoride prepa-rations in orthodontic patients. Angle Orthod, 70: 424–30, 2000.

21. Arhun N, Arman A. Effects of orthodontic mechanics on tooth enamel: A review. Semin Orthod, 13: 281–91, 2007.

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