This ex vivo study investigated the effect that repeated bracket displacement has on sliding friction and the magnitude of bracket displacement, and hence tooth movement, required to release bracket/archwire binding.
The design consisted of an ex vivo laboratory study. A jig was designed that allowed repeated displacement of a bracket to occur, while the resistance to sliding (friction) was measured using an Instron® universal testing machine. One type of stainless steel bracket was used in conjunction with four archwire types (0.016-inch stainless steel, 0.019 × 0.025-inch stainless steel, 0.021 × 0.025-inch stainless steel, 0.019 × 0.025-inch beta-titanium) and four magnitudes of displacement.
Repeated bracket displacement has a significant effect on the sliding resistance at the bracket/archwire interface (P < 0.001). The reduction in sliding resistance noted with displacement depended on the archwire. Over the range of displacements tested, there was an 85 and 80 per cent reduction associated with 0.021 × 0.025-inch and 0.019 × 0.025-inch stainless steel, respectively. For 0.019 × 0.025-inch beta-titanium and 0.016-inch stainless steel, these reductions were 27 and 19 per cent, respectively.
The importance of true friction, given the likelihood of bracket and/or archwire displacements in vivo, may be lessened.
AndersonD. J. (1956) Measurement of stress in mastication, Journal of Dental Research, 35, 671–673.
2.
AndreasenG. F. and QuevedoF. R. (1970) Evaluation of frictional forces in the 0.022×0.028 edgewise bracket in vitro, Journal of Biomechanics, 3, 151–160.
3.
AngolkarP. V., KapilaS., DuncansonM. G.Jr and NandaR. S. (1990) Evaluation of friction between ceramic brackets and orthodontic wires of four alloys, American Journal of Orthodontics and Dentofacial Orthopedics, 98, 499–506.
4.
BednarJ. R., GruendemanG.W. and SandrikJ. L (1991) A comparative study of frictional forces between orthodontic brackets and archwires, American Journal of Orthodontics and Dentofacial Orthopedics, 100, 513–522.
5.
BowdenF. P. and TaborD. (1974) Friction—An Introduction to Tribology, Heinemann, London.
6.
De BoeverJ. A., McCallW. D., HoldenS. and AshM. M. (1978a) Functional occlusal forces: an investigation by telemetry, Journal of Prosthetic Dentistry, 40, 326–333.
7.
De BoeverJ., McCallW. D., HoldenM. S. and AshM. M. (1978b) Functional occlusal forces under anaesthesia, Journal of Prosthetic Dentistry, 40, 402–408.
8.
DowningA., McCabeJ. and GordonP. (1994) A study of frictional forces between orthodontic brackets and archwires, British Journal of Orthodontics, 21, 349–357.
9.
DrescherD., BourauelC. and SchumacherH. A. (1989) Frictional forces between bracket and archwire, American Journal of Orthodontics and Dentofacial Orthopedics, 96, 397–404.
10.
FrankC. A. and NikolaiR. J. (1980) A comparative study of frictional resistances between orthodontic bracket and archwire, American Journal of Orthodontics, 78, 593–609.
11.
GarnerL. D., AllaiW.W. and MooreB. K. (1986) A comparison of frictional forces during simulated canine retraction of a continuous edgewise arch wire, American Journal of Orthodontics and Dentofacial Orthopedics, 90, 199–203.
12.
HixonE. H., AasenT. O., ArangoJ., ClarkR.A., KlostermanR., MillerS.S. and OdomW. M. (1970) On force and tooth movement, American Journal of Orthodontics, 57, 476–489.
13.
HoK. S. and WestV. C. (1991) Friction resistance between edgewise brackets and archwires, Australian Orthodontic Journal, 12, 95–99.
14.
InoueY. (1989) Biomechanical study on orthodontic tooth movement: changes in biomechanical property of the periodontal tissue in terms of tooth mobility, Osaka Daigku Shigaky Zasshi, 34, 291–305.
15.
Jost-BrinkmannP. and MiethkeR. R. (1991) Effects of tooth mobility on friction between bracket and wire (English Translation), Fortschritte der Kieferorthopedie, 52, 102–109.
16.
KapilaS., AngolkarP. V., DuncansonM.G. and NandaR. S. (1990) Evaluation of friction between edgewise stainless steel brackets and orthodontic wires of four alloys, American Journal of Orthodontics and Dentofacial Orthopedics, 98, 117–126.
17.
KeithO., KusyR.P. and WhitleyJ. Q. (1994) Zirconia brackets: an evaluation of morphology and coefficients of friction, American Journal of Orthodontics and Dentofacial Orthopedics, 106, 605–614.
18.
KusyR. P. and WhitleyJ. Q. (1988) Effect of surface roughness on frictional coefficients of archwires, Journal of Dental Research, 67 (Special issues), 361.
19.
KusyR. P. and WhitleyJ. Q. (1989) Effects of sliding velocity on the coefficients of friction in a model orthodontic system, Dental Materials, 5, 235–240.
20.
KusyR. P. and WhitleyJ. Q. (1990a) Coefficients of friction for archwires in stainless steel and polycrystalline alumina bracket slots. I. The dry state, American Journal of Orthodontics and Dentofacial Orthopedics, 98, 300–312.
21.
KusyR. P. and WhitleyJ. Q. (1990b) Effects of surface roughness on the coefficients of friction in model orthodontic systems, Journal of Biomechanics, 23, 913–925.
22.
KusyR. P., WhitleyJ.Q. and WiessM. J. (1990) Tribology of selected orthodontic arch wires and brackets, Journal of Dental Research, 69, 312.
23.
KusyR. P., WhitleyJ.Q. and PrewittM. J. (1991) Comparison of the frictional coefficients for selected archwire-bracket slot combinations in the dry and wet states, Angle Orthodontist, 61, 293–302.
24.
LiewC. F. (1993) The reduction of sliding friction between an orthodontic bracket and archwire by repeated vertical disturbance, Thesis, University of Queensland, Australia.
25.
MooreJ. C. and WatersN. E. (1993) Factors affecting tooth movement in sliding mechanics, European Journal of Orthodontics, 15, 235–241.
26.
MuhlemannH. R. (1954) Tooth mobility (V)— tooth mobility changes through artificial trauma, Journal of Periodontics, 25, 202–208.
27.
NikolaiR. J. (1975) An optimum orthodontic force theory as applied to canine retraction, American Journal of Orthodontics, 68, 290–302.
28.
OgataR. H., NandaR. S., DuncansonM. G.Jr., SinhaP. K. and CurrierG. F. (1996) Frictional resistances in stainless steel bracket-wire combinations with effects of vertical deflections, American Journal of Orthodontics and Dentofacial Orthopedics, 109, 535–542.
29.
OmanaH. M., MooreR.N. and BagbyM. D. (1992) Frictional properties of metal and ceramic brackets, Journal of Clinical Orthodontics, 26, 425–432.
30.
PictonD. C. A. (1964) Some implication of normal tooth mobility during mastication, Archives of Oral Biology, 9, 565–573.
31.
SimsA. P. T., WatersN. E., BirnieD. J. and PethybridgeR. J. (1993) A comparison of the forces required to produce tooth movement in vitro using two self-ligating brackets and a pre-adjusted bracket employing two types of ligation, European Journal of Orthodontics, 15, 377–385.
32.
TanneK., MatsubaraS, ShibaguchiT. and SakudaM. (1991) Wire friction from ceramic brackets during simulated canine retraction, Angle Orthodontist, 61, 285–290.
33.
TanneK., InoueY. and SakudaM. (1995) Biomechanical behavior of the periodontium before and after orthodontic tooth movement, Angle Orthodontist, 65, 123–128.
34.
TidyD. C. (1989) Frictional forces in fixed appliances, American Journal of Orthodontics and Dentofacial Orthopedics, 96, 249–254.
35.
TselepisM., BrockhurstP. and WestV. C. (1994) The dynamic frictional resistance between orthodontic brackets and arch wires, American Journal of Orthodontics and Dentofacial Orthopedics, 106, 131–138.
