Corrosion resistance of Cr-Ni-Mo steel in simulated body fluids

• Autorzy: Kajzer W. , Krauze A. , Walke W. , Marciniak J.
• Języki publikacji: EN

Abstrakty

EN

Purpose: The paper presents the comparison of corrosion resistance of Cr-Ni-Mo stainless steel in various corrosive media simulating human body fluids. Design/methodology/approach: The corrosion tests were realized by recording of anodic polarization curves with the use of the potentiodynamic method. The VoltaLab® PGP 201 system for electrochemical tests was applied. The tests were carried out in electrolyte simulating urine (pH = 6 ÷ 6.4), Tyrode’s physiological solution (pH = 6.8 ÷ 7.4) and plasma (pH = 7.2 ÷ 7.6) at the temperature of 37±1°C. Findings: Surface condition of metallic biomaterial determines its corrosion resistance. The highest values of breakdown potentials are recorded for electropolished and chemically passivated samples tested in artificial urine. The lowest values of anodic current density were recorded for samples tested in Tyrode’s physiological solution. Research limitations/implications: The obtained results are the basis for the optimization of physicochemical properties of the metallic biomaterial. Practical implications: On the basis of the obtained results it can be stated that stainless steel can be applied in reconstruction surgery, operative cardiology and urology. Originality/value: The paper presents the influence of various corrosive media simulating human body fluids on corrosion resistance of Cr-Ni-Mo stainless steel.

Słowa kluczowe

EN

metallic alloys; biomaterials; corrosion; body fluids

PL

stop metali; biomateriały; korozja; płyny ustrojowe

• Wydawca: International OCSCO World Press
• Czasopismo: Journal of Achievements in Materials and Manufacturing Engineering
• Rocznik: 2006
• Tom: Vol. 18, nr 1-2
• Strony: 115--118
• Opis fizyczny: Bibliogr. 24 poz., tab., wykr.

Twórcy

autor

Kajzer W.

• Division of of Biomedical Engineering, Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland

autor

Krauze A.

• Division of of Biomedical Engineering, Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland

autor

Walke W.

• Division of of Biomedical Engineering, Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland

autor

Marciniak J.

• Division of of Biomedical Engineering, Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland

Bibliografia

• [1] J. Marciniak: Perspectives of employing of the metallic biomaterials in the reconstruction surgery. Engineering of Biomaterials, 1, December 1997, pp.12-20.
• [2] S. Steinemann: Corrosion of surgical implants - in vivo, in-vitro tests in “Advances in Biomaterials”. Wintenet al John Viley Sons, Chirchester 1980, pp.1-4.
• [3] W. Kajzer, W. Chranowski, J. Marciniak: Corrosion resistance of Cr-Ni-Mo steel intended for urological stents. 11th International Scientific Conference on Contemporary Achievements in Mechanics, Manufacturing and Materials Science, Gliwice - Zakopane 2005 pp. 444-449.
• [4] Z. Paszenda, J. Tyrlik-Held: Forming the physicochemical properiteis of coronary stents surface. 13th Conference of the European Society of Biomechanics ESB2002, 1-4.09.2002, Wrocław, pp. 539-540.
• [5] Z. Paszenda, J. Tyrlik-Held: Coronary stents with passive and carbon layers. Proceedings of the 17th European Conference on Biomaterials ESB2002, 11-14.09.2003. Barcelona, pp. 89-90.
• [6] A. Krauze, A. Ziębowicz, J. Marciniak: Corrosion resistance of intramedullary nails used in elastic osteosynthesis of children. The Worldwide Congress of Materials and Manufacturing Engineering and Technology COMMENT'2005. Journal of Materials Processing Technology Vol. 162-163, 15 May 2005, pp. 209-214.
• [7] A. Krauze, W. Kajzer, J. Marciniak: Biomechanical characteristics of intramedullary nails - femur system with the use of FEM. Proceeding of the 12th International Scientific Conference „Achievements in Mechanical and Materials Engineering 2003”, Gliwice-Zakopane, 2003, pp. 533-538.
• [8] J. Szewczenko, J. Marciniak, W. Chrzanowski: Corrosion of Cr-Ni-Mo steel implants in conditions of sinusoidal current electrostimulation. Proceedings of the 9th International Scientific Conference „Achievements in Mechanical and Materials Engineering 2000”, Gliwice-Sopot-Gdańsk, 2000, pp. 511-514.
• [9] J. Marciniak, A. Ziębowicz, A. Krauze: Biomechanical characteristics of intramedullary nails - bone system in simulated laboratory conditions. Proceedings of the 9th International Scientific Conference „Achievements in Mechanical and Materials Engineering 2000”, Gliwice-Sopot-Gdańsk, 2000, pp. 367-370.
• [10] J. Szewczenko, J. Marciniak, W. Chrzanowski: Corrosion damages of Cr-Ni-Mo steel implants in conditions of an alternating current electrostimulation. Proceedings of the 10th Jubilee International Scientific Conference „Achievements in Mechanical and Materials Engineering 2001”, Gliwice-Kraków-Zakopane, 2001, pp. 543-548.
• [11] W. Walke, Z. Paszenda, J. Marciniak: Corrosion resistance of Co-Cr-W-Ni alloy designer for implants used in operative cafdiology. Engineering of Biomaterials, 47-53, (2005), pp. 96-99.
• [12] W. Kajzer, J. Marciniak: Biomechanical FEM analysis of stent-urethra system. ESB 2005 - 19th European Conference on Biomaterials (including the 4th Young Scientist Forum), Sorrento (Italy), 11-15.09.2005, pp. 618-619.
• [13] W. Kajzer, J. Marciniak: Biomechanical analysis of urological stent. Engineering of Biomaterials, 47-53, (2005), pp. 141-143.
• [14] W. Kajzer, M. Kaczmarek, J. Marciniak: Biomechanical analysis of stent - oesophagus system. The Worldwide Congress of Materials and Manufacturing Engineering and Technology COMMENT'2005, Journal of Materials Processing Technology Vol 162-163, 15 May 2005, pp. 196-202.
• [15] W. Walke, W. Kajzer, M. Kaczmarek, J. Marciniak: Stress and displacement analysis in conditions of coronary angioplasty. Proceedings of the 11th International Scientific Conference „Achievements in Mechanical and Materials Engineering 2002”, Gliwice-Zakopane, 2002 pp. 595-600.
• [16] W. Walke, Z. Paszenda, J. Marciniak: Optimization of coronary stent with the use of finite element method. Proceeding of the 12th International Scientific Conference „Achievements in Mechanical and Materials Engineering 2003”, Gliwice-Zakopane, 2003, pp.1011-1016.
• [17] W. Walke , Z. Paszenda, J. Filipiak: Experimental and numerical biomechanical analysis of vascular stent. Journal of Materials Processing Technology, COMMENT’2005, Journal of Materials Processing Technology Vol 164-165, 15 May 2005, pp. 1263-1268.
• [18] Z. Paszenda, J. Tyrlik-Held, J. Marciniak, A. Włodarczyk: Corrosion resistance of Cr-Ni-Mo steel intended for implants used in operative cardiology. Proceedings of the 9th International Scientific Conference „Achievements in Mechanical and Materials Engineering 2000”, Gliwice-Sopot-Gdańsk, 2000, pp. 425-428.
• [19] Z. Paszenda, J. Tyrlik-Held: Corrosion resistance of coronary stents made of Cr-Ni-Mo steel. Proceedings of the 10th Jubilee International Scientific Conference „Achievements in Mechanical and Materials Engineering 2001”, Gliwice-Kraków-Zakopane, 2001, pp. 453-460.
• [20] Standard: ASTM F-746-81:1999.
• [21] M. Multanen, M. Talja, S. Hallanvuo, A. Siitonen, T. Valimaa, T.L.J. Tammela, J. Seppala, P. Tormala: Bacterial adherence to ofloxacin-blended polylactone-coated self-reinforced - lactic acid polymer urological stents. BJU International, 86, 2000, pp. 966-969.
• [22] T. Valimaa, S. Laaksovirta: Degradation behaviour of self-reinforced 80L/20G PLGA devices in vitro. Biomaterials 25 (2004), pp.1225-1232.
• [23] J. Marciniak: Biomaterials. Edit by Silesian University of Technology (Wyd Pol. Śląskiej), Gliwice 2001, pp. 83, 212.
• [24] Standard PN – EN ISO 10993-15.