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The Control of Mineralization on Natural and Implant Surfaces

Published online by Cambridge University Press:  10 February 2011

G. H. Nancollas ,
W. Wu  and
R. Tang
G. H. Nancollas
Affiliation:
Chemistry Department, State University of New York at Buffalo, Amherst, NY14260
W. Wu
Affiliation:
Chemistry Department, State University of New York at Buffalo, Amherst, NY14260
R. Tang
Affiliation:
Chemistry Department, State University of New York at Buffalo, Amherst, NY14260
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Abstract

The generation of minerals such as calcium phosphates on the surfaces of dental and joint replacement implants is beneficial since the facilitation of bone formation permits their fixation. In contrast, the prevention of crystallization is desired on other surfaces such as kidney and cardiac valve prostheses. A key to the development of successful biomaterials is therefore an understanding of the factors that control crystal nucleation, growth and dissolution in aqueous solution. The Constant Composition method was used to investigate the influence of factors such as solution composition, ionic strength, pH and temperature on the crystallization and dissolution of the calcium phosphates, brushite (DCPD), octacalcium phosphate (OCP), hydroxyapatite (HAP) and fluorapatite (FAP). In parallel with these studies, a contact angle method along with surface tension component theory was employed to investigate the roles of interfacial free energy in mineralization and demineralization. Values of the interfacial tensions, -4.2, 4.3, 10.4 and 18.5 mJm-2 obtained from contact angle measurements for DCPD, OCP, HAP and FAP, respectively, compare well with those calculated from dissolution kinetics experiments and provide information concerning the growth and dissolution mechanisms. The exploitation of these approaches is illustrated in studies of the coating of specific calcium phosphate phases on titanium metal and alloy surfaces and nucleation and growth of OCP on polymer surfaces modified by silanization to produce amine- and carboxylterminated end groups. In all these reactions involving the calcium phosphates, concomitant dissolution reactions are often involved. Constant Composition kinetic studies have shown that the rate of these reactions decrease markedly with time despite a sustained driving force, and eventually, the rates approach zero even though crystals remain in the undersaturated solutions. Dissolution can be reinitiated by exposing the crystals to the solutions of different undersaturations. These results suggest that dislocation sizes play a significant role in the dissolution kinetic processes.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 599: Symposium DD – Mineralization in Natural & Synthetic Biomaterials , 1999 , 99
Copyright
Copyright © Materials Research Society 2000

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References

1. Lacefield, W. R. in Bioceramics: Materials Characterics Versus in Vivo behavior. Vol. 523. edited by Ducheyne, P. and Lemons, J.E. Annals of the New York Academy of Sciences, New York, 1988, pp. 7280.Google Scholar
2. Ellis, L. G., Nelson, D.G.A. and Featherstone, J.D.B., Biomaterials 13, p. 313(1992).Google Scholar
3. Dhert, W.J.A. Med. Prog. -Technol., 20, p. 143 (1994).Google Scholar
4. Ishizawa, H., Fujino, M. and Ogino, M., J. Biomed. Mater. Res., 29, p. 1,459 (1995).Google Scholar
5. Groot, K. de, Jansen, J.A., Wolke, CPAT. and van, C.A. Blitterswijk, in Hydroxyapatite Coatings in Orthopaedic Surgery. edited by Geesink, R.G.T. and Manley, M.T., Raven Press, New York, 1993, pp. 4962.Google Scholar
6. Yoshinari, M., Ohtsuka, Y. and Derand, T., Biomaterials, 15, p. 529 (1994).Google Scholar
7. Cui, F.Z., Luo, Z.S. and Feng, Q.L., J. Mater. Sci. Mater. Med., 8, p. 403 (1997).Google Scholar
8. Wolke, J.G.C. Sprayed and Sputtered Calcium Phosphate Coatings For Medical Implants, Ph.D. thesis, Nijmegen University, The Netherlands, 1997.Google Scholar
9. Cook, S.D., Thomas, K.A. and Jarcho, M. Clin. Orthopaed. Rel. Res., 230, p. 303 (1988).Google Scholar
10. Ducheyne, P., Radin, S., Heughbaert, M. and Heughbaert, J.C., Biomaterials 11, p. 244 (1990).Google Scholar
11. Fujishiro, Y., Sato, T. and Okuwaki, A., J. Mater. Sci. Mater. Med., 6, p. 172 (1995).Google Scholar
12. Weng, J. Bioactive, J. Coatings of Calcium Apatite by Plasma-Spraying Deposition, Ph.D. thesis, Leiden University, The Netherlands, 1995.Google Scholar
13. Dasarathy, H., Riley, C., Coble, H.D., Lacefield, W.R. and Maybee, G., J. Biomed. Mater. Res. 31, p. 81 (1996).Google Scholar
14. Haddao, D.B., James, P.F., and Noort, R. van, J. Mater. Sci. Mater. Med., 7, p. 255 (1996).Google Scholar
15. Li, T., Lee, J., Kobayashi, T. and Aoki, H., J. Mater. Sci. Mater. Med., 7, p. 355 (1996).Google Scholar
15. Ishikawa, K., Miyamoto, Y., Nagayama, M. and Asaoka, K., J. Biomedical Mater. Res. 38 p. 129 (1997).Google Scholar
16. Wang, C.K., Lin, J.H. Chern, Ju, C. P., Ong, H.C. and Chang, R.P.H., Biomaterials 18 p. 1,331 (1997)Google Scholar
17. Zhitomirsky, I. and Gal-Or, L., J. Mater. Sci. Mater. Med., 8, p. 213 (1997).Google Scholar
18. Feng, Q.L., Wang, H., Cui, F.Z. and Kim, T.N., J. Crystal Growth, 200, p. 550 (1999).Google Scholar
19. Zhang, J., Nancollas, G.H., J. Crystal Growth, 123, 59 (1992).Google Scholar
20. Zhang, J., Nancollas, G.H., J. Phys. Chem., 96, 5478 (1992).Google Scholar
21. JBudz, A., Nancollas, G.H., J. Crystal Growth, 91, 490 (1988).Google Scholar
22. MacInnis, I., Brantley, S., Geochim. Cosmochim. Acta, 56, 1113 (1991).Google Scholar
23. Wu, W. and Nancollas, G.H. Adv. Colloid Interface Sci., 79, 229 (1999).Google Scholar
24. Oss, C. J. van, Interfacial forces in aqueous media, Marcel Dekker, New York, 1994.Google Scholar
25. Mann, S., Heywood, B. R., Rajam, S. and Birchall, J. D., Proc. R. Soc. London, Ser., A 423, 457 (1989).Google Scholar
26. Heywood, B. R. and Mann, S., Langmuir, 8, 1492 (1992).Google Scholar
27. Titiloye, J. O., Parker, S. C., Osguthorpe, D. J. and Mann, S., J. Chem. Soc. Chem. Commun., 1494 (1991).Google Scholar
28. Weissbuch, I., Addadi, L., Lahav, M. and Leiserowitz, L., Science, 253, 637 (1991).Google Scholar
29. Addadi, L., L, I. Weissbuch, Vanmil, J., Shimon, L. J. W., Leiserowitz, L., Berkovitchyellin, Z. and Lahav, M., Angew. Chem. Int. Ed. Engl. 24, 466 (1985).Google Scholar
30. Chernov, A.A., Parvov, V.F., Kliya, M.O., Kostomarov, D.V., Kuzentsov, Yu.G., Soviet Phys. -Cryst., 26, 640 (1981).Google Scholar
31. Chernov, A.A., Crystal, J. Growth, 118, 333 (1992).Google Scholar
32. Teng, H.H., Dove, P.M., Orme, C., Yoreo, J.J., Science, 282, 724 (1998).Google Scholar
33. Christoffersen, J., Christoffersen, M.R., Crystal, J. Growth, 57, 21 (1982).Google Scholar
34. Blum, A., Lassaga, A., Nature, 331, 431 (1988).Google Scholar