Biyomateryallerde Yüzey Modifikasyonları: Metalik İmplantlarda Kaplamalar
Özet
Bu kitap, biyomedikal alanda metalik implantların yüzey modifikasyonlarıyla ilgili en son gelişmeleri ve kaplama teknolojilerini inceliyor. Metalik implantların yüzey özelliklerini optimize etmek ve biyouyumluluğunu artırmak amacıyla kullanılan çeşitli kaplama teknikleri ele alınıyor. Kitap, kaplama süreçlerinin temel prensiplerini, uygulama alanlarını ve avantajlarını açıklıyor. Ayrıca, farklı materyallerin ve kaplama yöntemlerinin karşılaştırmalı analizlerini sunuyor. Yüzey modifikasyonlarının biyolojik tepkileri nasıl etkilediğini anlamak da kitabın odak noktalarından biri. Bu kitap, biyomateryal araştırmacılarına, doktorlara, diş hekimlerine ve ilgili endüstri profesyonellerine metalik implantlarda kaplama teknolojileri konusunda bir el kitabı sunmayı hedefliyor.
This book examines the latest developments in surface modifications of metallic implants in the field of biomedical engineering and coating technologies. Various coating techniques used to optimize the surface properties of metallic implants and enhance their biocompatibility are discussed. The book explains the fundamental principles, application areas, and advantages of coating processes. Additionally, it presents comparative analyses of different materials and coating methods. Understanding how surface modifications affect biological responses is also a focal point of the book. The aim of this book is to provide a handbook on coating technologies in metallic implants for biomaterial researchers, doctors, dentists, and relevant industry professionals.
Referanslar
Park J. and Lakes R.S., (2007). Biomaterials an Introduction (Third Eition). USA, Springer, 1-13.
Geetha,M., A.K. Singh A.K., Asokamani, R. , Gogia, A.K. (2009). Ti based biomaterials, the ultimate choice for orthopaedic implants – A review. Progress in Materials Science 54, 397–425.
Narayan, R., (2009). Biomedical Materials. USA, Springer, 41-79.
Chen, Q., Thouas, G. A., (2015). Metallic implant biomaterials. Materials Science and Engineering: R: Volume 87, Pages 1-57.
Ducheyne, P., (2011). Comprehensive Biomaterials. USA, Elsevier,
Morsiya, C., A review on parameters affecting properties of biomaterial SS 316L, AUSTRALIAN JOURNAL OF MECHANICAL ENGINEERING2022, VOL. 20, NO. 3, 803–813.
Park, J. B. and Kim, Y. K., 1-12 Joyce Y. Wong Joseph D. Bronzino, BIOMATERIALS, 2007 by Taylor & Francis Group. LLC, Newyork
American Society for Testing and Materials, F139–86, p. 61, 1992.
Sumita, M., Hanawa, T., Teoh, S. H., (2004). Development of nitrogen-containing nickel-free austenitic stainless steels for metallic biomaterials—review. Materials Science and Engineering C 24, 753 – 760.
Niinomi, M., (2008). Metallic biomaterials. J Artif Organs ,11:105–110.
Balakrishnan, P., Sreekala M ,S, Thomas, S., (2018), FundamentalBiomaterials: Metals Woodhead Publishing is an imprint of Elsevier. Dr. J. Wilson, Chapter1
Zhang,Y., Wu, L., Guo, X., Kane, S., Deng, Y., Jung, Y.G., Lee, J. H. And Zhang J., (2018). Additive Manufacturing of Metallic Materials: A Review. JMEPEG (2018) 27:1–13.
Zhang, L. and Chen L. (2019). A Review on biomedical titanium alloys: recent progress and prospect. Advanced Engineer Materials, 21, 1801215.
Hao,Y., Li, S., Yang, R. (2016). Biomedical titanium alloys and their additive manufacturing. Rare Metals, 35(9):661–671.
Niinomi, M, (2003). Review Recent research and development in titanium alloys for biomedical applications and healthcare goods. Science and Technology of Advanced Materials, Volume 4, Issue 5, September 2003, Pages 445-454
Biesiekierski, A., Ping , D. H., Yamabe-Mitarai , Y., Wen, C., I. Cornides, Anne. Des. , 59 ( 2014 ) , s. 303 – 309
Rhoads, L. S., Silkworth, W. T., Roppolo, M. L., Whittingham, M. S., (2010). Cytotoxicity of nanostructured vanadium oxide on human cells in vitro. Toxicology in Vitro 24 (2010) 292–296.
Verstraeten, S.V., Aimo, L., Oteiza, P. I., (2008). Arch. Toxicol., 82, pp. 789-802.
Yokel, R.A., (2000). Neurotoxicology, 21, pp. 813-828
Lemons, J. E., Niemann, K.M.W., Weiss, A.B. , (1976). J. Biomed. Mater. Res., 10 pp. 549-553
Sezer, N., Evis, Z., Kayhan, S. M., Tahmasebifar, A., Koç, M. (2018). Review of magnesium-based biomaterials and their applications. Journal of Magnesium and Alloys, Volume 6, Issue 1, March 2018, Pages 23-43.
Biesiekierski, A., Wang, J., Gepreel, M. A., Wen, C., (2012). Review A new look at biomedical Ti-based shape memory alloys. Acta Biomaterialia, Volume 8, Issue 5, Pages 1661-1669.
Li, J., Tan, L., Wan, P.,Yu, X., Yang, K., (2015). Study on microstructure and properties of extruded Mg–2Nd–0.2Zn alloy as potential biodegradable implant material. Materials Science and Engineering: C, Volume 49, Pages 422-429
Chen, Y., Xu, Z., Smith, C., Sankar, J., (2014). Review Recent advances on the development of magnesium alloys for biodegradable implants. Acta Biomaterialia, Volume 10, Issue 11, Pages 4561-4573
Tosiriwatanapong T. and Singhatanadgit W., (2018). Review Zirconia-Based Biomaterials for Hard Tissue Reconstruction. Bone and Tissue Regeneration InsightsVolume 9.
Piconi, C., Maccauro, G., (1999). Review Zirconia as a ceramic biomaterial. Biomaterials 20 , 1 —25.
Uo, M., Sjoren, G., Sundh, A., Watari, F., Bergman, M., Lerner, U.,(2003). Cytotoxicity and bonding property of dental ceramics. Dental Materials, Volume 19, Issue 6, Pages 487-492
Garvıe, R. C., Urbanı, C., Kennedy, D. R. , Mcneuer , J. C., (1984). Biocompatibility of magnesia-partially stabilized zirconia (Mg-PSZ) ceramics. JOURNAL OF MATERIALS SCIENCE 19, 3224-3228.
Black, J., Clin. Mater., 16 (1994), pp. 167-173.
Balla, V. K., Banerjee, S., Bose, S., Bandyopadhyay, A., (2010). Direct laser processing of a tantalum coating on titanium for bone replacement structures. Acta Biomaterialia 6 (2010) 2329–2334.
Dittrick, S., Balla, V. K., Bose, S., Bandyopadhyay, A., (2011). Wear performance of laser processed tantalum coatings. Materials Science and Engineering: C, Volume 31, Issue 8, Pages 1832-1835.
Wong, K. V., and Hernandez, A. (2012). Review Article A Review of Additive Manufacturing. International Scholarly Research Network ISRN Mechanical Engineering Volume 2012, Article ID 208760, 10 pages.
Frazier , W. E.,(2014) Metal Additive Manufacturing: A Review. JMEPEG,23:1917–1928.
Bourell, D., Kruth, J. P., Leu, M., Levy, G., Rosen, D., Beese, A. M., Clare, A., (2017). Materials for additive manufacturing. CIRP Annals, Volume 66, Issue 2, Pages 659-681.
Herzog, D., Seyda, V., Wycisk, E., Emmelmann, C., (2016). By invitation only: overview article Additive manufacturing of metals. Acta Materialia, Volume 117,, Pages 371-392.
Abdulhameed, O., Al-Ahmari, A., Ameen,W., and Mian, S.H., (2019). Additive manufacturing: Challenges, trends, and applications. Advances in Mechanical Engineering Volume 11, Issue 2
Thijs, L. Verhaeghe, F., Craeghs, T., Humbeeck, J.V., Kruth, J.P., (2010). A study of the microstructural evolution during selective laser melting of Ti–6Al–4V. Acta Materialia 58,3303–3312.
Attar, H., Calin, M., Zhang, L.C., Scudino, S., Eckert, J., (2014). Manufacture by selective laser melting and mechanical behavior of commercially pure titanium. Materials Science and Engineering: A Volume 593, Pages 170-177.
Ferrar,B., Mullen, L., Jones, E., Stamp, R., Sutcliffe, C.J., (2012). Gas flow effects on selective laser melting (SLM) manufacturing performance. Journal of Materials Processing Technology Volume 212, Issue 2, Pages 355-364.
Fukuda, A., Takemoto, M., Saito, T., Fujibayashi, S., Neo, M., Pattanayak, D. K, Matsushita, T., Sasaki, K., Nishida, N., Kokubo, T., Nakamura, T., (2011). Osteoinduction of porous Ti implants with a channel structure fabricated by selective laser melting. Acta Biomaterialia Volume 7, Issue 5, Pages 2327-2336.
Bermani, S.E., Blackmore, M. L., Zhang, W. and Todd, I., (2010). The Origin of Microstructural Diversity, Texture, and Mechanical Properties in Electron Beam Melted Ti-6Al-4V. Metallurgıcal And Materıals Transactıons A, Volume 41A, p:3422-3434.
Murr, L. E., Gaytan, S.M. , Ceylan, A., Martinez, E., Martinez, J.L., Hernandez, D. H., Machado, B. I., Ramirez, D. A., Medina, F., Collins, S., Wicker, R. B., (2010). Characterization of titanium aluminide alloy components fabricated by additive manufacturing using electron beam melting. Acta Materialia, Volume 58, Issue 5, Pages 1887-1894.
Azarnia ,A., Colera, X.G., Mirzaali, M.J, Sovizi, S., Bartolome F., Weglowski , M.S., Wits, W. W., Yap, C. Y., Ahn, J., Miranda, G., Silva, F. S., Hosseini, H. R. M., Ramakrishna, S., Zadpoor , A. A., (2019). Additive manufacturing of Ti-6Al-4V parts through laser metal deposition (LMD): Process, microstructure, and mechanical properties. Journal of Alloys and Compounds Volume 804, Pages 163-191.
Yadroitsev, I., Bertrand,P., Smurov, I., (2007). Parametric analysis of the selective laser melting process. Applied Surface Science 253, 8064–8069.
Griesser, H., (2016). Thin Film Coatings for Biomaterials and Biomedical Applications. Woodhead Publishing Series in Biomaterials: Number 110. 16-19
Mahajana, A. and Sidhu, S. S., (2018). Surface modification of metallic biomaterials for enhanced functionality: a review. Materials technology, Vol. 33, no. 2, 93–105.
Patel, N. R. and Gohil, P. P., (2012). A Review on Biomaterials: Scope, Applications & Human Anatomy Significance. International Journal of Emerging Technology and Advanced Engineering, Volume 2, Issue 4.
Munir, M. U., Salman, S., Ihsan, A., Elsaman, T., (2022). Synthesis, Characterization, Functionalization and Bio-Applications of Hydroxyapatite Nanomaterials: An Overview. International Journal of Nanomedicine, Volume 17.
Mosas, K. K. A., Chandrasekar, A. R., Dasan, A., Pakseresht, A. and Galusek, D., (2022). Review Recent Advancements in Materials and Coatings for Biomedical Implants, Advancements in Materials and Coatings for Biomedical Implants. Gels, 8, 323.
Harun, W.S.W., Asri, R.I.M. , Alias, J., Zulkifli, F. H., Kadirgama, K., Ghani, S.A.C, Shariffuddin, J.H.M., (2018). Review article A comprehensive review of hydroxyapatite-based coatings adhesion on metallic biomaterials. Ceramics International 44,1250–1268.
Gomes, D.S., Santos, A. M. C., Neves, G. A., Menezes, R.R., (2019). A brief review on hydroxyapatite production and use in biomedicine. Cerâmica 65, 282-302.
Awasthi, S., Pandey, S. K., Arunan , E. and Srivastava, C., (2021). A review on hydroxyapatite coatings for the biomedical applications: experimental and theoretical perspectives. J. Mater. Chem. B, 9, 228.
Mejias, A., Candidato Jr, R.T., Pawłowski, L., Chicot, D., (2016). Mechanical properties by instrumented indentation of solution precursor plasma sprayed hydroxyapatite coatings: Analysis of microstructural effect. Surface and Coatings Technology, Volume 298, Pages 93-102.
Duta, L., Oktar, F. N., Stan, G.E., Pelin G. P., Serban, N., Luculescu, C., Mihailescu, I.N., (2013). Novel doped hydroxyapatite thin films obtained by pulsed laser deposition. Applied Surface Science, Volume 265, Pages 41-49.
Ji, X., Lou, W., Wang, Q., Ma, J., Xu, H., Bai, Q., Liu, C. and Liu J., (2012). Sol-Gel-Derived Hydroxyapatite-Carbon Nanotube/Titania Coatings on Titanium Substrates. Int. J. Mol. Sci. 2012, 13, 5242-5253.
Sandukas, S., Yamamoto, A., Rabiei, A., (2011). Osteoblast adhesion to functionally graded hydroxyapatite coatingsdoped with silver. Journal of Biomedical Materials Research Part A,Volume 97A, Issue 4, Pages375-536.
Huang, Y., Qiao, H., Nian, X., Zhang, X., Zhang, X., Song, G., Xu, Z., Zhang, H., Han, S., (2016). Improving the bioactivity and corrosion resistance properties of electrodeposited hydroxyapatite coating by dual doping of bivalent strontium and manganese ion. Surface & Coatings Technology 291,p. 205–215.
Dearnaley , G. Arps, J. H., (2005). Biomedical applications of diamond-like carbon (DLC) coatings: A review. Surface & Coatings Technology 200, 2518 – 2524.
Vishwakarma, V., Kaliaraj, G. S. and Mosas K.K.A., (2023). Review Multifunctional Coatings on Implant Materials—A Systematic Review of the Current Scenario. Coatings ,13(1), 69.
Dearnaley, G., Arps, J. H., (2005). Biomedical applications of diamond-like carbon (DLC) coatings: A review. Surface & Coatings Technology 200, p. 2518 – 2524.
Tiainen, V. M., (2001). Amorphous carbon as a bio-mechanical coating mechanical properties and biological applications. Diamond and Related Materials 10, p.153-160.
Dong , H., Shi, W. And Bell T., (1999). Potential of improving tribological performance of UHMWPE by engineering the Ti6Al4V counterfaces. Wear 225–229, 146–153.
Gutensohn, K., Beythien, C., Bau, J., Fenner, T., Grewe, P., Koester, R., Padmanaban, K. and Kuehnl, P., (2000). In Vitro Analyses of Diamond-like Carbon Coated Stents: Reduction of Metal Ion Release, Platelet Activation, and Thrombogenicity. Thrombosis Research 99, 577–585.
Hauert, R.,(2003). A review of modified DLC coatings for biological applications. Diamond and Related Materials 12 (2003) 583–589.
Ashfold, M. N. R., Claeyssens, F., Fuge G. M., and Henley, S. J., (2004). Pulsed laser ablation and deposition of thin films. Chem. Soc. Rev. ,3 3 , 23–3.
Lunney, J. G.,), Jordan, R. ,(1998). Pulsed laser ablation of metals. Applied Surface Science 127–129,941–946.
Harkönen, E., Tervakangas, S., Kolehmainen, J., Díaz, B., Swiatowska, J., Maurice, V., Seyeux, A., Marcus, P., Fenker, M., Toth, L., Radnoczi, G., Ritala, M., (2014). Interface control of atomic layer deposited oxide coatings by filtered cathodic arc deposited sublayers for improved corrosion protection. Materials Chemistry and Physics, Volume 147, Issue 3, Pages 895-907.
Kelly, P. J., Arnell, R. D., (2000). Magnetron sputtering: a review of recent developments and applications. Vacuum 56,159-172.
Clay, K.J., Speakman, S. P., Morrison, N. A., Tomozeiu, N., Milne, W. I., Kapoor, A., (1998). Material properties and tribological performance of rf-PECVD deposited DLC coatings, Diamond and Related Materials 7, 1100–1107.
Baba, K., Hatada, R., Flege, S., Ensinger, W., (2014). DLC coating of interior surfaces of steel tubes by low energy plasma source ion implantation and deposition. Applied Surface Science, Volume 310, Pages 262-265.
Hove, R. P., Sierevelt, I. N., Royen, B. J. and Nolte, P. A., (2015). Review Article Titanium-Nitride Coating of Orthopaedic Implants: A Review of the Literature. Hindawi Publishing Corporation BioMed Research International Volume 2015, Article ID 485975, 9 pages.
Al-Asadi, M. M. and Al-Tameemi, H. A., (2022). A review of tribological properties and deposition methods for selected hard protective coatings. Tribology International, Volume 176, 107919.
Paschoal, A. L., Vanâncio, E. C., Canale, L. C. F., Silva, O. L., Vilca, D. H. and Motheo, A. J., (2003). Metallic Biomaterials TiN-Coated: Corrosion Analysis and Biocompatibility. Artificial Organs, Volume 27, Issue 5, Pages397-499.
74. Hussein, M. A., Ankah, N. K. , Kumar, A. M., Azeem, M.A., Saravanan, S., Sorour, A.A. and Aqeeli, N. A., (2020). Mechanical, biocorrosion, and antibacterial properties of nanocrystalline TiN coating for orthopedic applications. Ceramics International, Volume 46, Issue 11, Part B, Pages 18573-18583.
Pradhan, S. K., Nouveau, C., Vasin, T. A.and Djouadi, M. A., (2005). Deposition of CrN coatings by PVD methods for mechanical application. Surface & Coatings Technology 200, p. 141 – 145.
Cunha, L., Andritschky, M., Pischow, K. and Wang, Z., (1999). Microstructure of CrN coatings produced by PVD techniques. Thin Solid Films 355-356, p. 465-471.
Li, H., Zhang, C. , Liu, C. and Huang, M., (2019). Improvement in corrosion resistance of CrN coatings. Surface and Coatings Technology, Volume 365, Pages 158-163.
Su, Y.L., Yao, S.H., (1997). On the performance and application of CrN coating. Wear 205, 112-119.
Fattah-alhosseini, A., Chaharmahali, R., Keshavarz, M. K., Babaei, K., (2021). Surface characterization of bioceramic coatings on Zr and its alloys using plasma electrolytic oxidation (PEO): A review. Surfaces and Interfaces, Volume 25, 101283.
Ul-Hamid, A., (2020). The effect of deposition conditions on the properties of Zr-carbide, Zr-nitride and Zr-carbonitride coatings – a review. Materials Advances,1,988.
Shen, G.X., Chen, Y.C., Lin, L., Lin, C. J.and Scantlebury, D.,(2005). Study on a hydrophobic nano-TiO2 coating and its properties for corrosion protection of metals. Electrochimica Acta 50, p. 5083–5089.
Utu, I.D., Marginean, G., Hulka, I., Serban, V.A. and Cristea, D., (2015). Properties of the thermally sprayed Al2O3–TiO2 coatings deposited on titanium substrate. International Journal of Refractory Metals and Hard Materials, Volume 51, Pages 118-123.
Lee, S. H., , Kım, H. W., Lee, E. J., Lı, L. H. and Kım, H. E., (2006). Hydroxyapatite–TiO2 hybrid coating on Ti implants. Journal of Biomaterials ApplicationsVolume 20, Issue 3, Pages195-302.
Liu, L., Bhatia, R. and Webste T. J., (2017). Atomic layer deposition of nano-TiO2 thin films with enhanced biocompatibility and antimicrobial activity for orthopedic implants. International Journal of Nanomedicine, Volume 12, Pages 8711-8723.
Karpagavalli, R., Zhou, A., Chellamuthu,P. and Nguyen, K., (2007). Corrosion behavior and biocompatibility of nanostructured TiO2 film on Ti6Al4V. Journal of Biomedical Materials Research Part A,Volume 83A, Issue 4,Pages 897-1216.
Wang, R., He, X., Gao, Y., Zhang, X., Yao, X. and Tang, B., (2017). Antimicrobial property, cytocompatibility and corrosion resistance of Zn-doped ZrO2/TiO2 coatings on Ti6Al4V implants. Materials Science and Engineering: C, Volume 75, Pages 7-15.
Yuan, W., Xia, D., Wu, S., Zheng, Y., Guan, Z., Rau, J. V., (2022). A review on current research status of the surface modification of Zn-based biodegradable metals. Bioactive Materials, Volume 7, Pages 192-216.
Robatto, B.M. H. , Álvarez , M. L., Azevedo, A. S., Dorado, J., Serra, J., Azevedo, N. F. and González, P., (2018). Pulsed laser deposition of copper and zinc doped hydroxyapatite coatings for biomedical applications. Surface and Coatings Technology, Volume 333, Pages 168-177.
Wang, Q., Wang, W., Li, Y., Li, W.,Tan, L. and Yang, K.,(2021). Biofunctional magnesium coating of implant materials by physical vapour deposition. Biomater Transl. 2021; 2(3): 248–256.
Pierson, H. O., Handbook of Chemical Vapor Deposition (CVD), Principles, Technology, and Applications, Second Edition • 1999
Mattox, D. M., Handbook of Physical Vapor Deposition (PVD) Processing, 2nd Edition, 2000.
Sakka, S., HANDBOOK of SOL–GEL SCIENCE and TECHNOLOGY Processing, Characterization and Applications, KLUWER ACADEMIC PUBLISHERS
Hench, L. L. and. West, J. K., The Sol-Gel Process, Chem. Rev, 1990, 90, 33-72.
Aliofkhazraei, A. M., Makhlouf, A. S. H., Handbook of Nanoelectrochemistry, Electrochemical Synthesis Methods, Properties, and Characterization Techniques, Springer International Publishing Switzerland 2015
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