Biomedical Engineering Reference
In-Depth Information
[12] G.J. Lee, et al., A quantitative AFM analysis of nano-scale surface roughness in various orthodontic
brackets, Micron 41 (7) (2010) 775
782.
[13] M. Redlich, et al., Improved orthodontic stainless steel wires coated with inorganic fullerene-like nano-
particles of WS(2) impregnated in electroless nickel-phosphorus film, Dent. Mater. 24 (12) (2008)
1640
1646.
[14] A. Katz, M. Redlich, L. Rapoport, H.D. Wagner, R. Tenne, Self-lubricating coatings containing
fullerene-like WS2 nanoparticles for orthodontic wires and other possible medical applications, Triboil.
Lett. 21 (2) (2006) 135
139.
[15] G.R. Samorodnitzky-Naveh, et al., Inorganic fullerene-like tungsten disulfide nanocoating for friction
reduction of nickel-titanium alloys, Nanomedicine (Lond) 4 (8) (2009) 943
950.
[16] A. Moshaverinia, et al., Modification of conventional glass-ionomer cements with N-vinylpyrrolidone
containing polyacids, nano-hydroxy and fluoroapatite to improve mechanical properties, Dent. Mater.
24 (10) (2008) 1381
1390.
[17] T. Uysal, et al., Are nano-composites and nano-ionomers suitable for orthodontic bracket bonding? Eur.
J. Orthod. 32 (1) (2010) 78
82.
[18] S.J. Ahn, et al., Experimental antimicrobial orthodontic adhesives using nanofillers and silver
nanoparticles, Dent. Mater. 25 (2) (2009) 206
213.
[19] R.R. Moraes, et al., Improved dental adhesive formulations based on reactive nanogel additives, J. Dent.
Res. (2011).
[20] G. Rahilly, N. Price, Nickel allergy and orthodontics, J. Orthod. 30 (2) (2003) 171
174.
[21] A.L. Greppi, D.C. Smith, D.G. Woodside, Nickel hypersensitivity reactions in orthodontic patients.
A literature review, Univ. Tor. Dent. J. 3 (1) (1989) 11
14.
[22] R. Lindsten, J. Kurol, Orthodontic appliances in relation to nickel hypersensitivity. A review, J. Orofac.
Orthop. 58 (2) (1997) 100
108.
[23] C.A. Pazzini, et al., Allergy to nickel in orthodontic patients: clinical and histopathologic evaluation,
Gen. Dent. 58 (1) (2010) 58
61.
[24] R.L. Bowen, Properties of a silica-reinforced polymer for dental restorations, J. Am. Dent. Assoc. 66
(1963) 57
64.
[25]
318.
[26] S.B. Mitra, D. Wu, B.N. Holmes, An application of nanotechnology in advanced dental materials, J. Am.
Dent. Assoc. 134 (10) (2003) 1382
1390.
[27] D.A. Terry, Direct applications of a nanocomposite resin system: Part 1—the evolution of contemporary
composite materials, Pract. Proc. Aesthet. Dent. 16 (6) (2004) 417
422.
[28] A.D. Wilson, B.E. Kent, A new translucent cement for dentistry. The glass ionomer cement, Br. Dent. J.
132 (4) (1972) 133
135.
[29] C.M. Killian, T.P. Croll, Nano-ionomer tooth repair in pediatric dentistry, Pediatr. Dent. 32 (7) (2010)
530
535.
[30] Y. Korkmaz, et al., Influence of different conditioning methods on the shear bond strength of novel
light-curing nano-ionomer restorative to enamel and dentin, Lasers Med. Sci. 25 (6) (2010) 861
866.
[31] M.M. O'Reilly, J.D.B. Featherstone, Demineralization and remineralization around orthodontic appli-
ances: an in vivo study, Am. J. Orthod. Dentofacial Orthoped. 92 (1) (1987) 33
40.
[32] B. Øgaard, G. Rølla, J. Arends, Orthodontic appliances and enamel demineralization: Part 1. Lesion
development, Am. J. Orthod. Dentofacial Orthop. 94 (1) (1988) 68
73.
[33] W.A. Wiltshire, Determination of fluoride from fluoride-releasing elastomeric ligature ties, Am. J.
Orthod. Dentofacial Orthop. 110 (4) (1996) 383
387.
[34] W.A. Wiltshire, In vitro and in vivo fluoride release from orthodontic elastomeric ligature ties, Am. J.
Orthod. Dentofacial Orthop. 115 (3) (1999) 288
292.
J.L. Ferracane, Current trends in dental composites, Crit. Rev. Oral. Biol. Med. 6 (4) (1995) 302
