OBJECTIVE: To study the effect of water storage on the bending properties of fiber-reinforced composite archwires and compare it to nickel-titanium (NiTi), stainless steel (SS), and beta-titanium archwires. MATERIALS AND METHODS: Align A, B, and C and TorQ A and B composite wires from BioMers Products, 0.014-, 0.016, and 0.018-inch, and 0.019×0.025-inch NiTi, 0.016-inch SS, and 0.019×0.025-inch beta-titanium archwires were tested (n=10/type/size/condition). A 20-mm segment was cut from each end of the archwire; one end was then stored in water at 37°C for 30 days, while the other was stored dry. The segments were tested using three-point bending to a maximum deflection of 3.1 mm with force monitored during loading (activation) and unloading (deactivation). Statistical analysis was completed via two-way analysis of variance with wire and condition (dry and water-stored) as factors. RESULTS: In terms of stiffness and force delivery during activation, in general: beta-titanium was >TorQ B>TorQ A>0.019×0.025-inch NiTi and 0.016-inch SS>Align C>0.018-inch NiTi>Align B>0.016-inch NiTi>Align A>0.014-inch NiTi. Water exposure was detrimental to the larger translucent wires (Align B and C, TorQ A and B) because they were more likely to craze during bending, resulting in decreased forces applied at a given deflection. Align A and the alloy wires were not significantly (P>.05) affected by water storage. Overall, the alloy wires possessed more consistent force values compared to the composite wires. CONCLUSION: Environmental conditions are more likely to affect fiber-reinforced composite archwires compared to alloy wires.
OBJECTIVE: To study the effect of water storage on the bending properties of fiber-reinforced composite archwires and compare it to nickel-titanium (NiTi), stainless steel (SS), and beta-titanium archwires. MATERIALS AND METHODS: Align A, B, and C and TorQ A and B composite wires from BioMers Products, 0.014-, 0.016, and 0.018-inch, and 0.019×0.025-inch NiTi, 0.016-inch SS, and 0.019×0.025-inch beta-titanium archwires were tested (n=10/type/size/condition). A 20-mm segment was cut from each end of the archwire; one end was then stored in water at 37°C for 30 days, while the other was stored dry. The segments were tested using three-point bending to a maximum deflection of 3.1 mm with force monitored during loading (activation) and unloading (deactivation). Statistical analysis was completed via two-way analysis of variance with wire and condition (dry and water-stored) as factors. RESULTS: In terms of stiffness and force delivery during activation, in general: beta-titanium was >TorQ B>TorQ A>0.019×0.025-inch NiTi and 0.016-inch SS>Align C>0.018-inch NiTi>Align B>0.016-inch NiTi>Align A>0.014-inch NiTi. Water exposure was detrimental to the larger translucent wires (Align B and C, TorQ A and B) because they were more likely to craze during bending, resulting in decreased forces applied at a given deflection. Align A and the alloy wires were not significantly (P>.05) affected by water storage. Overall, the alloy wires possessed more consistent force values compared to the composite wires. CONCLUSION: Environmental conditions are more likely to affect fiber-reinforced composite archwires compared to alloy wires.
Authors: Zheng-Ming Huang; R Gopal; K Fujihara; S Ramakrishna; P L Loh; W C Foong; V K Ganesh; C L Chew Journal: Biomaterials Date: 2003-08 Impact factor: 12.479
Authors: Vittorio Cacciafesta; Maria Francesca Sfondrini; Alessandro Lena; Andrea Scribante; Pekka K Vallittu; Lippo V Lassila Journal: Am J Orthod Dentofacial Orthop Date: 2008-03 Impact factor: 2.650
Authors: H Nakano; K Satoh; R Norris; T Jin; T Kamegai; F Ishikawa; H Katsura Journal: Am J Orthod Dentofacial Orthop Date: 1999-04 Impact factor: 2.650