Coatings such as diamond-like carbon (DLC) and titanium nitride (TiN) are employed in joint implants due to their excellent tribological properties. Recently, graphite-like carbon (GLC) and tantalum (Ta) have been proven to have good potential as coating as they possess mechanical properties similar to bones-high hardness and high flexibility. The purpose of this systematic literature review is to summarize the coating techniques of these four materials in order to compare their mechanical properties and tribological outcomes. Eighteen studies published between January 2000 and February 2013 have met the inclusion criteria for this review. Details of their fabrication parameters, material and mechanical properties along with the tribological outcomes, such as friction and wear rate, were identified and are presented in a systematic way. Although experiment conditions varied, we conclude that Ta has the lowest wear rate compared to DLC, GLC and TiN because it has a lower wear rate with high contact pressure as well as higher hardness to elasticity ratio. However, a further tribology test is needed in an environment which replicates artificial joints to confirm the acceptability of these findings.

Department of Biomedical Engineering Faculty of Engineering University of Malaya 50603 Kuala Lumpur Malaysia

Department of Biomedical Engineering Faculty of Engineering University of Malaya 50603 Kuala Lumpur Malaysia; Faculty of Mechanical Engineering Brno University of Technology Technická 2896 2 616 69 Brno Czech Republic

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Chen J, Wang Y, Li H, Ji L, Wu Y, Lv Y, Liu X, Fu Y and Zhou H. 2013. Microstructure, morphology and properties of titanium containing graphite-like carbon films deposited by unbalanced magnetron sputtering Tribol. Lett. 49 47–59

Hoseini M, Jedenmalm A and Boldizar A. 2008. Tribological investigation of coatings for artificial joints Wear 264 958–66

Xie D, Liu H, Deng X, Leng Y X and Huang N. 2009. Deposition of a-C:H films on UHMWPE substrate and its wear-resistance Appl. Surf. Sci. 256 284–8

Huang L-Y, Xu K-W, Lu J, Guelorget B and Chen H. 2001. Nano-scratch and fretting wear study of DLC coatings for biomedical application Diamond Relat. Mater. 10 1448–56

Manhabosco T M and Muller I L. 2009. Electrodeposition of diamond-like carbon (DLC) films on Ti Appl. Surf. Sci. 255 4082–6

Balagna C, Faga M G and Spriano S. 2012. Tantalum-based multilayer coating on cobalt alloys in total hip and knee replacement Mater. Sci. Eng. C 32 887–95

Spriano S, Vernè E, Faga M G, Bugliosi S and Maina G. 2005. Surface treatment on an implant cobalt alloy for high biocompatibility and wear resistance Wear 259 919–25

Narayan R J. 2005. Pulsed laser deposition of functionally gradient diamondlike carbon–metal nanocomposites Diamond Relat. Mater. 14 1319–30

Balla V K, Bhat A, Bose S and Bandyopadhyay A. 2012. Laser processed TiN reinforced Ti6Al4 V composite coatings J. Mech. Behav. Biomed. Mater 6 9–20 PubMed PMC

Jiang S-W, Jiang B, Li Y, Li Y-R, Yin G-F and Zheng C-Q. 2004. Friction and wear study of diamond-like carbon gradient coatings on Ti6Al4V substrate prepared by plasma source ion implant-ion beam enhanced deposition Appl. Surf. Sci. 236 285–91

Koseki H, Shindo H, Baba K, Fujikawa T, Sakai N, Sawae Y and Murakami T. 2008. Surface-engineered metal-on-metal bearings improve the friction and wear properties of local area contact in total joint arthroplasty Surf. Coat. Technol. 202 4775–9

Holmberg K and Matthews A. 1994. Coatings Tribology: Properties, Techniques and Applications in Surface Engineering vol 28 Dowson D. Amsterdam: Elsevier

Wood R J. Tribo-corrosion of coatings: a review. J. Phys. D: Appl. Phys. 2007;40:5502.

Antunes R A and De Oliveira M C L. 2009. Corrosion processes of physical vapor deposition-coated metallic implants Crit. Rev. Biomed. Eng. 37 425–60 PubMed

Fauchais P and Vardelle A. 2012. Thermal sprayed coatings used against corrosion and corrosive wear Advanced Plasma Spray Applications Rjeka: InTech; chapter 1

Voevodin A, O'neill J and Zabinski J. 1999. Tribological performance and tribochemistry of nanocrystalline WC/amorphous diamond-like carbon composites Thin Solid Films 342 194–200

Chowdhury S, Borham J, Catledge S A, Eberhardt A W, Johnson P S and Vohra Y K. 2008. Synthesis and mechanical wear studies of ultra smooth nanostructured diamond (USND) coatings deposited by microwave plasma chemical vapor deposition with He/H2/CH4/N2 mixtures Diamond Relat. Mater. 17 419–27 PubMed PMC

Blunt L, Bills P, Jiang X, Hardaker C and Chakrabarty G. 2009. The role of tribology and metrology in the latest development of bio-materials Wear 266 424–31

Yang S, Camino D, Jones A H S and Teer D G. 2000. Deposition and tribological behaviour of sputtered carbon hard coatings Surf. Coat. Technol. 124 110–6

Zardiackas L D, Parsell D E, Dillon L D, Mitchell D W, Nunnery L A and Poggie R. 2001. Structure, metallurgy and mechanical properties of a porous tantalum foam J. Biomed. Mater. Res. 58 180–7 PubMed

Balla V K, Bodhak S, Bose S and Bandyopadhyay A. 2010. Porous tantalum structures for bone implants: fabrication, mechanical and in vitro biological properties Acta Biomater. 6 3349–59 PubMed PMC

Findlay D M, Welldon K, Atkins G J, Howie D W, Zannettino A C W and Bobyn D. 2004. The proliferation and phenotypic expression of human osteoblasts on tantalum metal Biomaterials 25 2215–27 PubMed

Balla V, Bose S, Davies N and Bandyopadhyay A. 2010. Tantalum—a bioactive metal for implants J. Mineral. Metal Mater. Soc. 62 61–4

Fox V, Jones A, Renevier N M and Teer D G. 2000. Hard lubricating coatings for cutting and forming tools and mechanical components Surf. Coat. Technol. 125 347–53

Taeger G, Podleska L E, Schmidt B, Ziegler M and Nast-Kolb D. 2003. Comparison of diamond-like-carbon and alumina-oxide articulating with polyethylene in total hip arthroplasty Materialwissenschaft und Werkstofftechnik 34 1094–100

Paskvale S, Kahn M, Čekada M, Panjan P, Waldhauser W and Podgornik B. 2011. Tribological properties of diamond-like carbon coatings prepared by anode layer source and magnetron sputtering Surf. Coat. Technol. 205 Suppl. 2 S99–S102

Ali S S, Hardt J I, Quick K L, Sook Kim-Han J, Erlanger B F, Huang T-T, Epstein C J and Dugan L L. 2004. A biologically effective fullerene (C60) derivative with superoxide dismutase mimetic properties Free Radical Biol. Med. 37 1191–202 PubMed

Schneider A, Steinmueller-Nethl D, Roy M and Franek F. 2010. Enhanced tribological performances of nanocrystalline diamond film Int. J. Refractory Metals Hard Mater. 28 40–50

Mitura S K M, Niedzielski P, Louda P and Danilenko V. 2006. Nanocrystalline diamond, its synthesis, properties and applications J. Achievements Mater. Manuf. Eng. 16 9–16

Röstlund T, Albrektsson B, Albrektsson T and McKellop H. 1989. Wear of ion-implanted pure titanium against UHMWPE Biomaterials 10 176–81 PubMed

Stone D S, Yoder K B and Sproul W D. 1991. Hardness and elastic modulus of TiN based on continuous indentation technique and new correlation J. Vac. Sci. Technol. A 9 2543–7

Heide N S and j J W. 1993. Corrosion stability of TiN prepared by ion implantation and PVD Nucl. Instrum. Methods Phys. Res. B 80–81 467–71

Scarano A, Piattelli M, Vrespa G, Caputi S and Piattelli A. 2003. Bacterial adhesion on titanium nitride-coated and uncoated implants: an in vivo human study J. Oral Implantol. 29 80–5 PubMed

Raay J J A M, Rozing P M, Blitterswijk C A, Haastert R M and Koerten H K. 1995. Biocompatibility of wear-resistant coatings in orthopaedic surgery in vitro testing with human fibroblast cell cultures J. Mater. Sci: Mater. Med. 6 80–4

Lappalainen R and Santavirta S S. 2005. Potential of coatings in total hip replacement Clin. Orthop. Relat. Res. 430 72–9 PubMed

Marti A. 2000. Cobalt-base alloys used in bone surgery Injury 31 Suppl. 4 D18–D21 PubMed

Granchi D, Cenni E, Tigani D, Trisolino G, Baldini N and Giunti A. 2008. Sensitivity to implant materials in patients with total knee arthroplasties Biomaterials 29 1494–500 PubMed

Cobb A G and Schmalzreid T P. 2006. The clinical significance of metal ion release from cobalt–chromium metal-on-metal hip joint arthroplasty Proc. Inst. Mech. Eng. H 220 385–98 PubMed

Greenwald A S. 2001. Alternative Bearing Surfaces: The Good, The Bad, and the Ugly Surgeons A A O O. (San Francisco, CA: JBJS Am; ) pp 68–72 PubMed

Elias C N, Lima J H C, Valiev R and Meyers M A. 2008. Biomedical applications of titanium and its alloys JOM 60 46–9

Herman Shah Abd Rahman D C, Abu Osman N C, Shasmin H N and Wan Abu Bakar W A. 2013. In vivo and in vitro outcomes of alumina, zirconia and their composited ceramic-on-ceramic hip joints J. Ceram. Soc. Japan 121 382–7

Lima M S F, Folio F and Mischler S. 2005. Microstructure and surface properties of laser-remelted titanium nitride coatings on titanium Surf. Coat. Technol. 199 83–91

Camino D, Jones A H S, Mercs D and Teer D. 1999. High performance sputtered carbon coatings for wear resistant applications Vacuum 52 125–31

Bunshah R F. 1982. Deposition technologies: an overview Deposition Technologies for Films and Coatings: Developments and Applications (Park Ridge, NJ: Noyes Publication; ) 1–18

Su Y, Yao S, Leu Z, Wei C and Wu C. 1997. Comparison of tribological behavior of three films—TiN, TiCN and CrN—grown by physical vapor deposition Wear 213 165–74

Lawn B R. 2002. Ceramic-based layer structures for biomechanical applications Curr. Opin. Solid State Mater. Sci. 6 229–35

Choy K L. 2003. Chemical vapour deposition of coatings Prog. Mater. Sci. 48 57–170

Liu Y, Erdemir A and Meletis E I. 1996. A study of the wear mechanism of diamond-like carbon films Surf. Coat. Technol. 82 48–56

Casiraghi C, Ferrari A. and Robertson J. Raman spectroscopy of hydrogenated amorphous carbons. Phys. Rev. B. 2005;72:085401.

Dipankar Choudhury R W, Shirvani A and Mootanah R. 2013. The influence of honed surfaces on metal-on-metal hip joints Japan. Soc. Tribol. 8 195–202

Jacobson S and Hogmark S. 2002. On the tribological character of boundary lubricated DLC coated components Tribol. Ser. 40 337–45

Li X D and Bhushan B. 1999. Micro/nanomechanical and tribological characterization of ultrathin amorphous carbon coatings J. Mater. Res. 14 2328–37

Sondi I, Salopek-Sondi B, Škapin S D, Šegota S, Jurina I and Vukelić B. 2011. Colloid-chemical processes in the growth and design of the bio-inorganic aragonite structure in the Scleractinian coral Cladocora caespitosa J. Colloid Interface Sci. 354 181–9 PubMed

Piconi C, Maccauro G and Muratori F. 2004. Bioceramics in Joint Arthroplasty Lazennec J-Y and Dietrich M (Darmstadt: Steinkopff; ) 105–9

Puértolas J A, Martínez-Nogués V, Martínez-Morlanes M J, Mariscal M D, Medel F J, López-Santos C and Yubero F. 2010. Improved wear performance of ultra high molecular weight polyethylene coated with hydrogenated diamond like carbon Wear 269 458–65

Tsubone D, Hasebe T, Kamijo A and Hotta A. 2007. Fracture mechanics of diamond-like carbon (DLC) films coated on flexible polymer substrates Surf. Coat. Technol. 201 6423–30

Rieker C P K. 2002. In vivo tribological performance of 231 metal-on-metal hip articulations Hip Int. 12 73–6 PubMed

Matthews J B, Green T R, Stone M H, Mike Wroblewski B, Fisher J and Ingham E. 2000. Comparison of the response of primary human peripheral blood mononuclear phagocytes from different donors to challenge with model polyethylene particles of known size and dose Biomaterials 21 2033–44 PubMed

Smith R A and Hallab N J. 2010. In vitro macrophage response to polyethylene and polycarbonate-urethane particles J. Biomed. Mater. Res. Part A 93 347–55 PubMed

Green T R, Fisher J, Matthews J B, Stone M H and Ingham E. 2000. Effect of size and dose on bone resorption activity of macrophages by in vitro clinically relevant ultra high molecular weight polyethylene particles J. Biomed. Mater. Res. 53 490–7 PubMed

Minn M and Sinha S K. 2010. Tribology of ultra high molecular weight polyethylene film on Si substrate with chromium nitride, titanium nitride and diamond like carbon as intermediate layers Thin Solid Films 518 3830–6

Sinha S K. 2002. Wear Failures of Plastics vol 11 (Materials Park, OH: ASM International

Park S J, Lee K-R and Ko D-H. 2005. Tribological behavior of nano-undulated surface of diamond-like carbon films Diamond Relat. Mater. 14 1291–6

Vamsi Krishna Balla S B and Bandyopadhyay A. 2010. Direct laser processing of tantalum coating on titanium for bone replacement structures Acta Biomater. 6 2329–34 PubMed PMC

Hauert R. 2003 A. review of modified DLC coatings for biological applications Diamond Relat. Mater. 12 583–9

Kwok S C H, Wang J and Chu P K. 2005. Surface energy, wettability, and blood compatibility phosphorus doped diamond-like carbon films Diamond Relat. Mater. 14 78–85

McKellop H, Clarke I, Markolf K and Amstutz H. 1981. Friction and wear properties of polymer, metal and ceramic prosthetic joint materials evaluated on a multichannel screening device J. Biomed. Mater. Res. 15 619–53 PubMed

Schildhauer T A, Robie B, Muhr G and Köller M. 2006. Bacterial adherence to tantalum versus commonly used orthopedic metallic implant materials J. Orthopaedic Trauma 20 476–84 PubMed

Love C A, Cook R B, Harvey T J, Dearnley P A and Wood R J K. 2013. Diamond like carbon coatings for potential application in biological implants—a review Tribol. Int. 63 141–50

Serro A P, Completo C, Colaço R, dos Santos F, da Silva C L, Cabral J M S, Araújo H, Pires E and Saramago B. 2009. A comparative study of titanium nitrides, TiN, TiNbN and TiCN, as coatings for biomedical applications Surf. Coat. Technol. 203 3701–7

He W, Yu R, Wang H and Yan H. 2005. Electrodeposition mechanism of hydrogen-free diamond-like carbon films from organic electrolytes Carbon 43 2000–6

Golden T D. 2004. Improvement of homogeneity and adhesion of diamond-like carbon films on copper substrates. MSc Thesis University of North Texas (available at: http://digital.library.unt.edu/ark:/67531/metadc4565/)

Van der Biest O O and Vandeperre L J. 1999. Electrophoretic deposition of materials Annu. Rev. Mater. Sci. 29 327–52

Saikko V, Calonius O and Keranen J. 2004. Effect of slide track shape on the wear of ultra-high molecular weight polyethylene in a pin-on-disc wear simulation of total hip prosthesis J. Biomed. Mater Res. B Appl. Biomater. 69 141–8 PubMed

Leyland A and Matthews A. 2000. On the significance of the H/E ratio in wear control: a nanocomposite coating approach to optimised tribological behaviour Wear 246 1–11

Akkurt S. 1995. On the effect of surface roughness on wear of acetal-metal gear pairs Wear 184 107–9

Balagna C, Spriano S and Faga M G. 2012. Characterization of Co–Cr–Mo alloys after a thermal treatment for high wear resistance Mater. Sci. Eng. C 32 1868–77 PubMed

Wang Y J, Li H X, Ji L, Liu X H, Wu Y X, Lv Y H, Fu Y Y, Zhou H D. and Chen J M. Synthesis and characterization of titanium-containing graphite-like carbon films with low internal stress and superior tribological properties. J. Phys. D: Appl. Phys. 2012;45:295301.

Ohgoe Y, Hirakuri K K, Saitoh H, Nakahigashi T, Ohtake N, Hirata A, Kanda K, Hiratsuka M and Fukui Y. 2012. Classification of DLC films in terms of biological response Surf. Coat. Technol. 207 350–4

Manhabosco T M and Müller I L. 2009. Tribocorrosion of diamond-like carbon deposited on Ti6Al4V Tribol. Lett. 33 193–7

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