Two approaches to form antibacterial surface: Doping with bactericidal element and drug loading

Applied Surface Science

Volumn 330, Issue , 2015, Pages 339-350

  Sukhorukova, I V ^a   Sheveyko, A N ^a   Kiryukhantsev Korneev, Ph V ^a   Anisimova, N Y ^b   Gloushankova, N A ^b   Zhitnyak, I Y ^b   Benesova, J ^c,d   Amler, E ^c,e   Shtansky, D V ^a  

^a NATIONAL UNIVERSITY OF SCIENCE AND TECHNOLOGY MISIS   (Russian Federation)

^b N N BLOKHIN RUSSIAN CANCER RESEARCH CENTER   (Russian Federation)

^c INSTITUTE OF EXPERIMENTAL MEDICINE   (Czech Republic)

^d CHARLES UNIVERSITY   (Czech Republic)

^e CZECH TECHNICAL UNIVERSITY IN PRAGUE   (Czech Republic)

Author keywords

Antibacterial activity; Bioactive nanostructured films; Cell proliferation; Drug release

Indexed keywords

BIOCOMPATIBILITY; CALCIUM COMPOUNDS; CELL PROLIFERATION; COMPOSITE FILMS; CONTROLLED DRUG DELIVERY; DENSITY (OPTICAL); DENSITY MEASUREMENT (OPTICAL); DRUG PRODUCTS; FILM PREPARATION; GLOW DISCHARGES; LASER HEATING; MASS SPECTROMETRY; OPTICAL EMISSION SPECTROSCOPY; PHOSPHATASES; SCANNING ELECTRON MICROSCOPY; SEMICONDUCTOR DOPING; SILVER; SINTERING; TARGETED DRUG DELIVERY; TITANIUM COMPOUNDS;

ALKALINE PHOSPHATASE ACTIVITY; ANTI-BACTERIAL ACTIVITY; ANTIBACTERIAL SURFACES; CROSS-SECTIONAL MORPHOLOGY; DRUG RELEASE; GLOW-DISCHARGE OPTICAL EMISSION SPECTROSCOPY; NANOSTRUCTURED FILMS; SELECTIVE LASER SINTERING;

SILVER COMPOUNDS;

EID: 84924085406     PISSN: 01694332     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apsusc.2014.12.119     Document Type: Article

References (40)

1. D. Bhowmik, H. Gopinath, B. Pragati Kumar, S. Duraivel, and K.P. Sampath Kumar Controlled release drug delivery systems Pharma Innov. 1 2012 24 32
2. Y. Perrie, and T. Rades Chapter 1, Controlling Drug Delivery, Pharmaceutics: Drug Delivery and Targeting 2012 Pharmaceutical Press 1 24
3. K.C. Popat, M. Eltgroth, T.J. La Tempa, C.A. Grimes, and T.A. Desai Decreased Staphylococcus epidermis adhesion and increased osteoblast functionality on antibiotic-loaded titania nanotubes Biomaterials 28 2007 4880 4888
4. H. Kang, D.J. Kim, S. Park, J. Yoo, and Y.S. Ryu Controlled drug release using nanoporous anodic aluminum oxide on stent Thin Solid Films 515 2007 5184 5187
5. J. Salonen, A.M. Kaukonen, J. Hirvonen, and V. Lehto Mesoporous silicon in drug delivery applications J. Pharm. Sci. 97 2008 632 653
6. J.M. Rogers-Foy, D.L. Powers, D.A. Brosnan, S.F. Barefoot, R.J. Friedman, and M. LaBerge. Hydroxyapatite composites designed for antibiotic drug delivery and bone reconstruction: a caprine model J. Invest. Surg. 12 1999 263 275
7. X. Chen, Q.W. Li, and X.M. Wang Chapter 8: Gold Nanostructures for Bioimaging, Drug Delivery and Therapeutics, Precious Metals Biomedical Applications 2014 163 176
8. J.S. Price, A.F. Tencer, D.M. Arm, and G.A. Bohach Controlled release of antibiotics from coated orthopedic implants J. Biomed. Mater. Res. 30 1996 281 286
9. P. Horcajada, A. Ramila, J. Perez-Pariente, and M. Vallet-Reg. Influence of pore size of MCM-41 matrices on drug delivery rate Microporous Mesoporous Mater. 68 2004 105 109
10. S.I. Shen, B.R. Jasti, and X. Li Chapter 22, Design of Controlled Release Drug Delivery Systems. Standard Handbook of Biomedical Engineering and Design 2003 McGraw-Hill
11. C.R. Arciola, D. Campoccia, P. Speziale, L. Montanaro, and J.W. Costerton Biofilm formation in Staphylococcus implant infections. A review of molecular mechanisms and implications for biofilm-resistant materials Biomaterials 33 2012 5967 5982
12. 2 coatings on stainless steel deposited by RF magnetron sputtering Vacuum 86 2011 235 241
13. Y. Kuo, J. Lee, C. Wang, and Y. Chang The effect of Cu content on the microstructures, mechanical and antibacterial properties of Cr-Cu-N nanocomposite coatings deposited by pulsed DC reactive magnetron sputtering Surf. Coat. Technol. 202 2007 854 860
14. B. Li, X. Liu, F. Meng, J. Chang, and C. Ding Preparation and antibacterial properties of plasma sprayed nano-titania/silver coatings Mater. Chem. Phys. 118 2009 99 104
15. W. Chen, Y. Liu, H.S. Courtney, M. Bettenga, C.M. Agrawal, J.D. Bumgardner, and J.L. Ong In vitro anti-bacterial and biological properties of magnetron co-sputtered silver-containing hydroxyapatite coating Biomaterials 27 2006 5512 5517
16. V. Kotharu, R. Nagumothu, C.B. Arumugam, M. Veerappan, S. Sankaran, M. Davoodbasha, and T. Nooruddin Fabrication of corrosion resistant, bioactive and antibacterial silver substituted hydroxyapatite/titania composite coating on Cp Ti Ceram. Int. 38 2012 731 740
17. P.J. Kelly, H. Li, P.S. Benson, K.A. Whitehead, J. Verran, R.D. Arnell, and I. Iordanova Comparison of the tribological and antimicrobial properties of CrN/Ag, ZrN/Ag, TiN/Ag, and TiN/Cu nanocomposite coatings Surf. Coat. Technol. 205 2010 1606 1610
18. P.J. Kelly, H. Li, K.A. Whitehead, J. Verran, R.D. Arnell, and I. Iordanova A study of the antimicrobial and tribological properties of TiN/Ag nanocomposite coatings Surf. Coat. Technol. 204 2009 1137 1140
19. A. Masse, A. Bruno, M. Bosetti, A. Biasibetti, M. Cannas, and P. Gallinaro Prevention of pin track infection in external fixation with silver coated pins: clinical and microbiological results J. Biomed. Mater. Res. 53 2000 600 604
20. C.N. Kraft, M. Hansis, S. Arens, M.D. Menger, and B. Vollmar Striated muscle microvascular response to silver implants: a comparative in vivo study with titanium and stainless steel J. Biomed. Mater. Res. 49 2000 192 199
21. Y.F. Zheng, B.B. Zhang, B.L. Wang, Y.B. Wang, L. Li, Q.B. Yang, and L.S. Cui Introduction of antibacterial function into biomedical TiNi shape memory alloy by the addition of element Ag Acta Biomater. 7 2011 2758 2767
22. D.V. Shtansky, N.A. Gloushankova, I.A. Bashkova, M.A. Kharitonova, T.G. Moizhess, A.N. Sheveiko, F.V. Kiryukhantsev-Korneev, M.I. Petrzhik, and E.A. Levashov Multifunctional Ti-(Ca,Zr)-(C,N,O,P) films for load-bearing implants Biomaterials 27 2006 3519 3531
23. D.V. Shtansky, E.A. Levashov, I.V. Batenina, N.A. Gloushankova, N.Y. Anisimova, M.V. Kiselevsky, and I.V. Reshetov Recent progress in the field of multicomponent bioactive nanostructured films RCS Adv. 3 2013 11107 11115
24. D.V. Shtansky, I.V. Batenina, and I.A. Yadroitcev A new combined approach to metal-ceramic implants with controllable surface topography, chemistry, blind porosity, and wettability Surf. Coat. Technol. 208 2012 14 23
25. E.A. Levashov, Yu.S. Pogozhev, A.S. Rogachev, N.A. Kochetov, and D.V. Shtansky Self-propagating high-temperature synthesis of composite targets based on titanium carbonitride, silicide and aluminide for ion-plasma deposition of multifunctional coatings Russ. J. Non-Ferrous Metals 53 2012 77 84
26. J.M. Andrews Determination of minimum inhibitory concentrations J. Antimicrob. Chemother. 48 2001 5 16
27. A.N. Sheveyko, I.V. Batenina, F.V. Kirukhancev-Korneev, and D.V. Shtansky Comparative studies of the structure and chemical properties of nanocomposite coatings TiCaPCON-Ag Prot. Met. Phys. Chem. Surf. 51 2015 (in press)
28. V.N. Kislenko, N.M. Kolichev, and R.G. Gosmanov Veterinary Microbiology and Immunology 2012 GEOTAR-Media Moscow 752 (in Russian)
29. NCCLS Performance Standards for Antimicrobial Susceptibility Testing; Ninth Informational Supplement M100-S9 19 1999 1
30. B. Cao, R. Peng, Z. Li, and J. Ding Effects of spreading areas and aspect ratios of single cells on dedifferentiation of chondrocytes Biomaterials 35 2014 6871 6881
31. R.H. Christenson Biochemical markers of bone metabolism: an overview Clin. Biochem. 30 1997 573 593
32. D.V. Shtansky, I.V. Batenina, F.V. Kiryukhantsev-Korneev, A.N. Sheveyko, K.A. Kuptsov, N.Y. Anisimova, I. Zhitnyak, and N.A. Gloushankova Ag- and Cu-doped multifunctional bioactive nanostructured TiCaPCON films Appl. Surf. Sci. 285P 2013 331 343
33. D.-H. Song, S.-H. Uhma, S.-B. Lee, J.-G. Hanc, and K.-N. Kim Antimicrobial silver-containing titanium oxide nanocomposite coatings by a reactive magnetron sputtering Thin Solid Films 519 2011 7079 7085
34. J. Wang, Z. Wang, S. Guo, J. Zhang, Y. Song, X. Dong, X. Wang, and J. Yu Antibacterial and anti-adhesive zeolite coatings on titanium alloy surface Microporous Mesoporous Mater. 146 2011 216 222
35. D.-H. Song, S.-H. Uhm, S.-E. Kim, J.-S. Kwon, J.-G. Han, and K.-N. Kim Synthesis of titanium oxide thin films containing antibacterial silver nanoparticles by a reactive magnetron co-sputtering system for application in biomedical implants Mater. Res. Bull. 47 2012 2994 2998
36. 2 -Ag antibacterial coatings for human fetal osteoblasts Acta Biomater. 8 2012 4191 4197
37. C. Dai, Y. Yuan, C. Liu, J. Wei, H. Hong, X. Li, and X. Pan Degradable, antibacterial silver exchanged mesoporous silica spheres for hemorrhage control Biomaterials 30 2009 5364 5375
38. C. Damm, H. Munstedt, and A. Rosch Long-term antimicrobial polyamide 6/silver-nanocomposites J. Mater. Sci. 42 2007 6067 6073
39. C. Damm, and H. Munstedt Kinetic aspects of the silver ion release from antimicrobial polyamide/silver nanocomposites Appl. Phys. A 91 2008 479 486
40. D.V. Shtansky, A.S. Grigoryan, A.K. Toporkova, A.N. Sheveiko, and Ph.V. Kiruykhantsev-Korneev Modification of polytetrafluoroethylene implants by deposition of multifunctional bioactive nanostructured films with and without stem cells Surf. Coat. Technol. 206 2011 1188 1195