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Biocompatibility Studies of the Nitinol Thin Films

Published online by Cambridge University Press:  15 February 2011

C.Z. Dinu ,
R. Tanasa ,
V.C. Dinca ,
A. Barbalat ,
C. Grigoriu ,
E.O. Bucur ,
A. Dauscher ,
V. Ferrari DeStefano  and
M. Dinescu
C.Z. Dinu
Affiliation:
National Institute for Laser, Plasma and Radiation Physics, PO Box MG–16, RO 76900, Bucharest, Romania
R. Tanasa
Affiliation:
Pasteur Institute S.A, Calea Giulesti 333, Bucharest, 77 826, Romania
V.C. Dinca
Affiliation:
National Institute for Laser, Plasma and Radiation Physics, PO Box MG–16, RO 76900, Bucharest, Romania
A. Barbalat
Affiliation:
National Institute for Laser, Plasma and Radiation Physics, PO Box MG–16, RO 76900, Bucharest, Romania
C. Grigoriu
Affiliation:
National Institute for Laser, Plasma and Radiation Physics, PO Box MG–16, RO 76900, Bucharest, Romania
E.O. Bucur
Affiliation:
Pasteur Institute S.A, Calea Giulesti 333, Bucharest, 77 826, Romania
A. Dauscher
Affiliation:
Laboratories of Materials Physic (LPM), INPL, Ecole des Mines de Nancy, Parc de Saurupt, F-54042 Nancy, France
V. Ferrari DeStefano
Affiliation:
University of Rome “La Sapienza”, Dept. of Electronics, 00186 Rome, Italy
M. Dinescu
Affiliation:
National Institute for Laser, Plasma and Radiation Physics, PO Box MG–16, RO 76900, Bucharest, Romania
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Abstract

Pulsed Laser Deposition method (PLD) was used to grow nitinol (NiTi) thin films with goal of investigating their biocompatibility. High purity Ni and Ti targets were alternatively ablated in vacuum with a laser beam (λ=355 nm, 10 Hz) and the material was collected on room temperature Ti substrates. X-ray diffraction, scanning electron microscopy, energy dispersive spectroscopy and atomic force microscopy analyses have been performed to investigate the chemical composition, crystalline structure and surface morphology of the NiTi films. The nitinol layers biocompatibility has been tested using as a metric the extent to which the cells adhere during the culture period on the surface of NiTi layers deposited on Ti substrates. Vero and fibroblast cell lines dispersed into MEM (Eagle) solution containing 8% fetal bovine serum, at 37° C, were used for tests. Preliminary studies indicate that the interaction at the interface is specifically controlled by the surface morphology, (especially by surface roughness), and by the chemical state of the surface. Cell behavior after contact with NiTi/Ti structure for different intervals (18, 22 and 25 days for the Vero cells, and after 10 and 25 days for fibroblasts) supports the conclusion that NiTi is a very good candidate as a biocompatible material.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 780: Symposium Y – Advanced Optical Processing of Materials , 2003 , Y4.9
Copyright
Copyright © Materials Research Society 2003

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References

references

1. Thierry, B., Tabrizian, M., Savadago, O., Yahia, L., Effects of sterlization processes on NiTi alloy: surface characterization, J. Biomed Mater Res 2000, 49:8898.Google Scholar
2. Wever, D.J., Velduizen, A.G., Sanders, M.M., Schakenraad, J.M., van Horn, J.R., Cytotoxic, allergic and genotoxic activity of a nickel- titanium alloy, Biomaterials 1997; 18: 11151120.Google Scholar
3. Trepanier, C., Tabrizian, M., Yahia, L., Bilodeau, L., Piron, D.L., Effect of modification of oxide layer on NiTi stent corrosion resistance, J. Biomed. Mater. Res. (Appl. Biomater.) 1998; 43:433440.Google Scholar
4. Trepanier, C., Leung, T. K., Tabrizian, M., Yahia, L., Bienvenu, J.G., Tanguay, J.F., Piron, D.L., Bilodeau, L., Preliminary investigation of the effects of surface treatments on biological response to shape memory NiTi stents, J. Biomed. Mater. Res. (Appl. Biomater.) 1999; 48:165171 Google Scholar
5. Wataha, J.C., Lockwood, P.E., Marek, M., Ghazi, M., Ability of Ni-containing biomedical alloys to active monocytes and endothelial cells in vitro, Biomed. Mater. Res. 1999; 45: 251257.Google Scholar
6. Assad, M., Lemieux, N., Rivard, C.H., Yahia, L., Comparative in vitro biocompatibility of nickel- titanium, pure nickel, pure titanium and stainless steel: genotoxicity and atomic absorption evaluation, Biomed. Mater Eng. 1999; 9:112.Google Scholar
7. Rae, T. (1986) In: Techniques of Biocompatibility Testing, Volume II, Williams, D.F., ed., CRC Press, Boca Raton, FL, 81.Google Scholar
8. Rae, T. Flow Manual. Flow Laboratories Ltd, Victoria Park, Irvine, 1974, 108 Google Scholar
9. RI, Freshney. Culture of animal cells. A manual of basic technique. Third edition, Wiley-Liss, Inc., New York, 1994, p. 127147.Google Scholar
10. Tanasa, R. Contributions to the study of some animal lentiviroses. DSc (PhD) Thesis. Bucharest University of Agronomic Sciences and Veterinary Medicine, 2001, p. 124138 (in Romanian).Google Scholar
11. Brailovski, V., Trochu, F., 1996. Review of shape memory alloys medical applications in Russia. Bio-Medical of Materials & Engineering 6 (4), 291298.Google Scholar
12. Rutner, B., Surface properties of biomaterials, Biomaterial Science, Academic Press, 1996, 2134.Google Scholar
13. Wen, X., Wang, X., Zhang, N., Micro-rough surface of metallic biomaterials, Review, BioMed. Mater. Eng., 1996; 6: 173189.Google Scholar
14. Shabalovskaya, A. S., Surface, corrosion and biocompatibility aspects of Nitinol as an implant material, Bio- Medical Materials and Eng. 12, 2002: 69109.Google Scholar
15. Chrisey, D.B., Hubler, G.H., Pulsed Laser Deposition of Thin Films, Eds. John Wiley, INC. 229 1994.Google Scholar
16. Gumbiner, B.M., Proteins associated with the cytoplasmic surface of adhesion molecules, Neuron 11, 1993, 551564.Google Scholar
17. JM, Anderson, TL, Bonfield & NP, Ziats (1990) Protein adsorption and cellular adhesion and activation on biomedical polymers. Int.J.Artif.Organs 13: 375382.Google Scholar
18. Groth, T, Altankov, G & Klosz, K (1994) Adhesion of human peripheral blood lymphocytes is dependent on surface wettability and protein preadsorption. Biomaterials 15: 423428.Google Scholar
19. Pytela, R, MD, Pierschbacher & Ruoslahti, E (1985) Identification and isolation of a 140 kd cell surface glycoprotein with properties expected of a fibronectin receptor. Cell 40: 191198.Google Scholar
20. Ruoslahti, E & MD, Pierschbacher (1987) New perspectives in cell adhesion: RGD and integrins. Science 238: 491497.Google Scholar
21. Shabalovskaya, S., Anderagg, J., Sachdeva, R., Harmon, B., Preliminary XPS spectroscopic characterization of autoclaved NiTi shape memory alloys for implants, Biomaterials for Drug and Cell Delivery, MRS, Vol.331, 1994:239244.Google Scholar
22. Gerber, H & SM, Perren (1980) Evaluation of tissue compatibility of in vitro cultures of embryonic bone. In: GD, Winter, JL, Leray & K, de Groot (Eds) Evaluation of Biomaterials, Wiley, New York, p 307314.Google Scholar