Evaluate the Load Deflection Properties of Titanium Orthodontic Archwires Coated with Zirconium: An In Vitro Study

Muftah Ali Abdelaaziz; Khaled Abdela Mahdi Ali

المؤلفون

Muftah Ali Abdelaaziz Department of Dental Technology, Faculty of Health Sciences, Sirte University, Libya
Khaled Abdela Mahdi Ali Central Dental Clinic, Health Services, Sebha, Libya

الكلمات المفتاحية:

titanium orthodontic archwires، load deflection، coating - 3-point bending test

الملخص

The purpose of this study was to evaluate the load deflection characteristics and analyze the compositions of two products of titanium orthodontic archwires after surface coating. Timonium titanium archwires (TIM) and beta-titanium orthodontic archwires (β-Ti III) were obtained from (3M Unitek® USA and TIM orthodontic archwires 3M and TP Orthodontics® USA). The electron beam physical vapor deposition (EB PVD) was used to coat (5, 10, 25, and 50 thick) of pouring Zr on chose archwires. The load deflection properties were assessed by the modified bending test utilizing a 3-point bend structure, the samples were held in slots with underpins 10 mm apart and displaced at the midpoint. The wires were set up as straight of lengths of 14 mm. A 3-point bending test was performed with a Hounsfield test machine. load deflection tests demonstrated significant contrasts between Zr-covered archwires coated and uncoated archwires. A high load deflection rate was shown by the coated β-Ti III archwires and a low load deflection avoidance rate was displayed by the coated TIM archwires. Load deflection test of 1 mm demonstrated comparable forces for both uncoated β-Ti III archwires and those coated with 5 nm Zr was 250g. The value for β-Ti III archwires coated with 10, 25 and 50 nm Zr, was up to 261g. In this way, the coating of 5 nm Zr on β-Ti III archwires have not shown decrease in an archwires quality while coating of 10, 25 and 50 nm Zr have displayed increments in archwires deflection force. β-Ti III archwires contain strong elements, for example, Mo and Zr and coating of 5, 10, 25, and 50 nm Zr might improve the deflection force for titanium orthodontic archwires.

المراجع

Chen, Qizhi, and George A. Thouas. "Metallic implant biomaterials." Materials Science and Engineering: R: Reports 87 (2015): 1 57.

Has an, Muhammad K., and Subhash C. Anand. "Medical and healthcare devices: materials perspective." Journal of Education and Technical Science s 1.1 (2014): 10 13.

Park, B. J., and Young Kon Kim. "Metallic biomaterials." Balance 1 (2003): 50.

Geetha, Manivasaga m, et al. "Ti based biomaterials, the ultimate choice for orthopaedic implants a review." Progress in materials science 54.3 (2009): 397 425.

Geetha, N. Textbook of Physiology for Dental Students. Paras Medical Publisher ,

Kusy, Robert P., John Q. Whi tley, and Júlio de Araújo Gurgel. "Comparisons of surface roughnesses and sliding resistances of 6 titanium based or TMA type archwires." American journal of orthodontics and dentofacial orthopedics 126.5 (2004): 589 603.

Chang, Hong Po, and Yu Chuan Tseng . "A novel β titanium alloy orthodontic wire." The Kaohsiung journal of medical sciences 34.4 (2018): 202 206.

Carrion Vilches, Francisco J., Maria Dolores Bermudez, and Paula Fructuoso. "Static and kinetic friction force and surface roughness of different archwirebracket sliding contacts." Dental materials journal 34.5 (2015): 648 653.

Tecco, Simona, Stefano Tetè, and Felice Festa. "Friction between archwires of different sizes, cross section and alloy and brackets ligated with low friction or conventional ligatures." The Angle Orthodontist 79.1 (2009): 111 116.

Mousavi, Seyed Mohammad, et al. "Effect of esthetic coating on surface roughness of orthodontic archwires." International orthodontics 15.3 (2017): 312 321.

Bartzela, Theodosia N., Christiane Senn, and Andrea Wichelhaus. "Load deflection characteristics of superelastic nickel titanium wires." The Angle Orthodontist 77 . 6 (2007): 991 998.

Krishnan, Vinod, and K. Jyothindra Kumar. "Mechanical properties and surface characteristics of three archwire all oys." The Angle Orthodontist 74 . 6 (2004): 825 831.

Burstone, Charles J., and A. Jon Goldberg. "Maximum forces and deflections from orthodontic appliances." American journal of orthodontics 84. 2 (1983): 95 103.

Burstone, Charles J., Bai Qin, and John Y. Mo rton. "Chinese NiTi wire a new orthodontic alloy." American journal of orthodontics 87 . 6 (1985): 445 452.

Schaus, J. G., and R. J. Nikolai. "Localized, transverse, flexural stiffnesses of continuous arch wires." American Journal of Orthodontics 89 . 5 (198 6): 407 414.

Miura, Fujio, Masakuni Mogi, Yoshiaki Ohura, and Hitoshi Hamanaka. "The super elastic property of the Japanese NiTi alloy wire for use in orthodontics." American Journal of Orthodontics and Dentofacial Orthopedics 9 0 . 1 (1986): 1 10.

Berger, J . E. F. F., and T. Waram. "Force levels of nickel titanium initial archwires." Journal of Clinical Orthodontics 41 . 5 (2007):

Oltjen, Jay M., Manville G. Duncanson Jr, Joydeep Ghosh, Ram S. Nanda, and G. Frans Currier. "Stiffness deflection behavior o f selected orthodontic wires." The Angle Orthodontist 67 . 3 (1997): 209 218.

Singh, Jogender, and Douglas Edward Wolfe. "Review Nano and macro structured component fabrication by electron beam physical vapor deposition (EB PVD)." Journal of materials Scien ce 40.1 (2005): 1 26.

Bruno, Alexander Dmitrievich, and Anastasia Vladimirovna Parusnikova. "Local expansions of solutions to the fifth Painlevé equation." Doklady Mathematics. 83. 3. 2011