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http://dx.doi.org/10.5395/rde.2012.37.1.16

Effect of fluoride concentration in pH 4.3 and pH 7.0 supersaturated solutions on the crystal growth of hydroxyapatite  

Shin, Han-Eol (Department of Conservative Dentistry, Yonsei University College of Dentistry)
Park, Sung-Ho (Department of Conservative Dentistry, Yonsei University College of Dentistry)
Park, Jeong-Won (Department of Conservative Dentistry, Gangnam Severance Hospital, Yonsei University College of Dentistry)
Lee, Chan-Young (Department of Conservative Dentistry, Yonsei University College of Dentistry)
Publication Information
Restorative Dentistry and Endodontics / v.37, no.1, 2012 , pp. 16-23 More about this Journal
Abstract
Objectives: Present study was undertaken to investigate the crystal growth onto synthetic hydroxyapatite (HA) seeds in pH 4.3 and pH 7.0 supersaturated solutions with different fluoride concentrations. Materials and Methods: 8 groups of pH 4.3 and 7.0 calcium phosphate supersaturated solutions were prepared with different fluoride concentrations (0, 1, 2 and 4 ppm). Calcium phosphate precipitates yield crystal growth onto the HA seed surface while solutions flow. For evaluation of crystallizing process, the changes of $Ca^{2+}$, $PO{_4}^{3-}$, $F^-$ concentrations of the inlet and outlet solutions were determined. The recovered solid samples were weighed to assess the amount of minerals precipitated, and finally determined their composition to deduce characteristics of crystals. Results: During the seeded crystal growth, there were significantly more consumption of $Ca^{2+}$, $PO{_4}^{3-}$, $F^-$ in pH 4.3 solutions than pH 7.0 (p < 0.05). As fluoride concentration increased in pH 4.3 solution, $Ca^{2+}$, $PO{_4}^{3-}$, $F^-$ consumption in experimental solutions, weight increment of HA seed, and fluoride ratio in crystallized samples were increased. There were significant differences among the groups (p < 0.05). But in pH 7.0 solution, these phenomena were not significant. In pH 7.0 solutions, analyses of crystallized samples showed higher Ca/P ratio in higher fluoride concentration. There were significant differences among the groups (p < 0.05). But in pH 4.3 solution, there were not significant differences in Ca/P ratio. Conclusions: Crystal growth in pH 4.3 solutions was superior to that in pH 7.0 solutions. In pH 4.3 solutions, crystal growth increased with showed in higher fluoride concentration up to 4 ppm.
Keywords
Fluoride concentration; Hydroxyapatite; pH; Seeded crystal growth;
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1 Margolis HC, Moreno EC. Kinetic and thermodynamic aspects of enamel demineralization. Caries Res 1985;19:22-35.   DOI
2 Aoba T. Solubility properties of human tooth mineral and pathogenesis of dental caries. Oral Dis 2004;10:249-257.   DOI
3 Robinson C, Brookes SJ, Bonass WA, Shore RC, Kirkham J. Enamel maturation. Ciba Found Symp 1997;205:156-170.
4 Nancollas GH, Mohan MS. The growth of hydroxyapatite crystals. Arch Oral Biol 1970;15:731-745.   DOI
5 Aoba T, Moreno EC. Preparation of hydroxyapatite crystals and their behavior as seeds for crystal growth. J Dent Res 1984;63:874-880.   DOI
6 Barone JP, Nancollas GH, Tomson M. The seeded growth of calcium phosphates. The kinetics of growth of dicalcium phosphate dihydrate on hydroxyapatite. Calcif Tissue Res 1976;21:171-182.   DOI
7 Eanes ED. The influence of fluoride on the seeded growth of apatite from stable supersaturated solutions at pH 7.4. J Dent Res 1980;59:144-150.   DOI
8 Elliot JC. Studies in inorganic chemistry: structure and chemistry of the apatites and other calcium orthophosphates. Amsterdam: Elsevier; 1994. p111.
9 Robinson C, Connell S, Kirkham J, Brookes SJ, Shore RC, Smith AM. The effect of fluoride on the developing tooth. Caries Res 2004;38:268-276.   DOI
10 Yanagisawa T, Takuma S, Tohda H, Fejerskov O, Fearnhead RW. High resolution electron microscopy of enamel crystals in cases of human dental fluorosis. J Electron Microsc (Tokyo) 1989;38:441-448.
11 Amjad Z, Nancollas GH. Effect of fluoride on the growth of hydroxyapatite and human dental enamel. Caries Res 1979;13:250-258.   DOI
12 Cate JM, Arends J. Remineralization of artificial enamel lesions in vitro. Caries Res 1977;11:277-286.   DOI
13 Han WS, Kum KY, Lee CY. The influence of fluoride on remineralization of artificial dental caries. J Korean Acad Cons Dent 1996;21:161-173.
14 Lammers PC, Borggreven JM, Driessens FC. Influence of fluoride on in vitro remineralization of artificial subsurface lesions determined with a sandwich technique. Caries Res 1990;24:81-85.   DOI
15 Feagin F, Patel PR, Koulourides T, Pigman W. Study of the effect of calcium, phosphate, fluoride and hydrogen ion concentrations on the remineralization of partially demineralized human and bovine enamel surfaces. Arch Oral Biol 1971;16:535-548.   DOI
16 Featherstone JD, Rodgers BE, Smith MW. Physicochemical requirements for rapid remineralization of early carious lesions. Caries Res 1981;15:221-235.   DOI
17 Kim MK, Kum KY, Lee CY. The influence of pH on remineralization of artificial dental caries. J Korean Acad Cons Dent 1997;22:193-208.
18 Kwun JW, Kim KY, Lee SJ, Jung IY, Lee CY. The effect of the supersaturated solutions containing high concentrations of fluoride on seeded crystal growth. J Korean Acad Cons Dent 1999;24:330-336.
19 Barone JP, Nancollas GH. The growth of calcium phosphates on hydroxyapatite crystals. The effect of fluoride and phosphonate. J Dent Res 1978;57:735-742.   DOI
20 Mura-Galelli MJ, Narusawa H, Shimada T, Iijima M, Aoba T. Effects of fluoride on precipitation and hydrolysis of octacalcium phosphate in an experimental model simulating enamel mineralization during amelogenesis. Cells Mater 1992;2:221-230.
21 Lee CY, Aoba, T. Seeded crystal growth onto enamal mineral and synthetic hydroxyapatite in dilute supersaturated solutions containing low concentration of fluoride. J Korean Acad Cons Dent 1995;20:818-826.
22 Oh SY, Jung IY, Kum KY, Lee CY. Effects of fluoride concentration and seed material on seeded crystal growth. J Korean Acad Cons Dent 1997;22:560-574.
23 Iijima M, Moradian-Oldak J. Control of apatite crystal growth in a fluoride containing amelogenin-rich matrix. Biomaterials 2005;26:1595-1603.   DOI
24 Fan Y, Nelson JR, Alvarez JR, Hagan J, Berrier A, Xu X. Amelogenin-assisted ex vivo remineralization of human enamel: effects of supersaturation degree and fluoride concentration. Acta Biomater 2011;7:2293-2302.   DOI
25 Matsumoto T, Okazaki M, Inoue M, Sasaki J, Hamada Y, Takahashi J. Role of acidic amino acid for regulating hydroxyapatite crystal growth. Dent Mater J 2006;25: 360-364.   DOI
26 Iijima M, Tohda H, Suzuki H, Yanagisawa T, Moriwaki Y. Effects of F- on apatite-octacalcium phosphate intergrowth and crystal morphology in a model system of tooth enamel formation. Calcif Tissue Int 1992;50:357-361.   DOI
27 Aoba T. The effect of fluoride on apatite structure and growth. Crit Rev Oral Biol Med 1997;8:136-153.   DOI
28 Song YJ. Doctoral Dissertation, Graduate School of Yonsei University; 2009, Development of diffusion pathway in the initial enamel caries lesion.
29 Kwon JW, Suh DG, Song YJ, Lee Y, Lee CY. The effect of lactic acid concentration and pH of lactic acid buffer solutions on enamel remineralization. J Korean Acad Cons Dent 2008;33:507-517.   DOI
30 Yamazaki H, Margolis HC. Enhanced enamel remineralization under acidic conditions in vitro. J Dent Res 2008; 87:569-574.   DOI
31 Song SC. Doctoral Dissertation, Graduate School of Yonsei University; 2011, Effect of fluoride on remineralization of artificial enamel caries in pH 4.3 and pH 7.0 remineralized solution.
32 Kwak YJ, Kim ES, Park SH, Gong HK, Lee Y, Lee CY. The remineralizing features of pH 5.5 solutions of different degree of saturations on artifically demineralized enamel. J Korean Acad Cons Dent 2008;33:481-492.   DOI
33 Yi JS, Roh BD, Shin SJ, Lee Y, Kong HK, Lee CY. The dynamic change of artificially demineralized enamel by degree of saturation of remineralization soultion at pH 4.3. J Korean Acad Cons Dent 2009;34:20-29.   DOI
34 Park JS, Park SH, Park JW, Lee CY. The remineralization aspect of enamel according to change of the degree of saturation of the organic acid buffering solution in pH 5.5. J Korean Acad Cons Dent 2010;35:96-105.   DOI
35 Eanes ED, Meyer JL. The influence of fluoride on apatite formation from unstable supersaturated solutions at pH 7.4. J Dent Res 1978;57:617-624.   DOI
36 LeGeros RZ. Calcium phosphates in oral biology and medicine. Monogr Oral Sci 1991;15:1-201.
37 Nelson DG, Featherstone JD, Duncan JF, Cutress TW. Effect of carbonate and fluoride on the dissolution behaviour of synthetic apatites. Caries Res 1983;17: 200-211.   DOI
38 Wu W, Nancollas GH. Determination of interfacial tension from crystallization and dissolution data: a comparison with other methods. Adv Colloid Interface Sci 1999;79:229-279.   DOI