Investigation on synergistic effects of Laser surface texturing and TiAlN coating on the tribological properties and antibacterial performance of Ti6Al4V alloy
Restricted accessResearch articleFirst published online 2026
Investigation on synergistic effects of Laser surface texturing and TiAlN coating on the tribological properties and antibacterial performance of Ti6Al4V alloy
The present study aims to examine the antibacterial and tribological properties of Ti6Al4V alloy using surface texturing and Titanium Aluminium Nitride (TiAlN) coating treatments. The goal is to enhance the service life of medical implants by improving both bacterial and wear resistance. The samples were tested against Escherichia coli using an amoxicillin disc as a reference antibacterial agent to identify distinct Zones of Inhibition (ZOI) around the treated samples after a 24- h incubation period. The surface-modified samples exhibited improved COF performance (9%) and a nearly 50% reduction in wear rate when tested under a sliding wear tribometer, corroborated by SEM and EDX analysis. Statistical analysis confirmed that the improvements are highly significant, with p < 0.0001. The TiAlN coating applied to the untreated and laser-treated specimens exhibited the largest ZOI in the range of 4 to 4.3 mm. The resulting antibacterial properties of the surface-modified Ti6Al4V alloy suggest its suitability for bioimplants, as it helps prevent biofilm formation.
PhilipJTMathewJKuriachenB. Tribology of Ti6Al4V: a review. Friction2019; 7: 497–536.
2.
MarinELanzuttiA. Biomedical applications of titanium alloys: a comprehensive review. Materials (Basel)2024; 17: 14.
3.
MarkhoffJGrabowN. Wear and corrosion in medical applications. Current Directions in Biomedical Engineering2020; 6: 434–437.
4.
WangX.Overview on biocompatibilities of implantable biomaterials. In: Advances in biomaterials science and biomedical applications.London: InTechOpen, 2013. 10.5772/53461
5.
AliSAbdul RaniAMBaigZ, et al.Biocompatibility and corrosion resistance of metallic biomaterials. Corros Rev2020; 38: 381–402.
6.
WangXXuSZhouS, et al.Titanium-based alloys and composites for orthopedic implant applications: a comprehensive review. Mater Des2024; 241: 112850.
7.
PrakashTChockalingamK. Investigation of the mechanical, corrosive wear and biological behaviour of titanium–5 manganese–tricalcium phosphate composites produced by powder metallurgy for hip implants. J Mater Eng Perform2025; 34: 15260–15276.
8.
SarrafMRezvani GhomiEAlipourS, et al.A state-of-the-art review of the fabrication and characteristics of titanium and its alloys for biomedical applications. Bio-Design and Manufacturing2021; 5: 1–25.
9.
RaganyaLMoshokoaNObadeleBA, et al.Microstructural and mechanical characterization of the β-type ti-11.1Mo-10.8Nb alloy for biomedical applications. IOP Conf Ser: Mater Sci Eng2019; 655: 012025.
10.
AissaniLNouveauCWalockMJ, et al.Influence of vanadium on structure, mechanical and tribological properties of CrN coatings. Surf Eng2015; 31: 779–788.
11.
ZhangLChenL. A review on biomedical titanium alloys: recent progress and prospect. Adv Eng Mater2019; 21: 1801215.
12.
OkazakiYChinzeiK. Development of orthopedic implants with highly biocompatible Ti alloys. In: In: High entropy materials: microstructures and properties. London: InTechOpen, 2022. 10.5772/intechopen.105389
13.
LuXWuZXuK, et al.Multifunctional coatings of titanium implants toward promoting osseointegration and preventing infection: recent developments. Front Bioeng Biotechnol2021; 9: 783816. 10.3389/fbioe.2021.783816
14.
SinghIGeorgeSMTiwariA, et al.Influence of laser surface texturing on the wettability and antibacterial properties of metallic, ceramic and polymeric surfaces. J Mater Res2021; 36: 3985–3999.
15.
AbuAliaMFullamSCinottiF, et al.Titanium nitride coatings on CoCrMo and Ti6Al4 V alloys: effects on wear and ion release. Lubricants2024; 12: 96.
16.
UwaisZAHusseinMASamadMA, et al.Surface modification of metallic biomaterials for better tribological properties: a review. Arab J Sci Eng2017; 42: 4493–4512.
17.
Danışman Ş, Odabaş D and Teber M. Effect of TiN. Tialn and TiCN thin films obtained by reactive magnetron sputtering on the wear behaviour of Ti6Al4 V alloy: a comparative study. Coatings2022; 12: 1238.
18.
MuniyappanASridharHPViswanathanJ, et al.Tribological performance of surface textured CoCrMo alloy with TiN coating: an experimental study using pin-on-disc tribometer and predictive modelling with ANN. AIP Conf Proc2025; 3360: 020004.
19.
BanaszekKJanuszewiczBWołowiecE, et al.Complex XRD and XRF characterization of TiN–TiCN–TiC surface coatings for medical applications. Solid State Phenomena2015; 225: 159–168.
20.
WangSWangFLiaoZ, et al.Tribological behaviour of titanium alloy modified by carbon–DLC composite film. Surf Eng2015; 31: 934–941.
21.
JabbarSAbdulsadaSA. Corrosion resistance and antibacterial property of hydroxyapatite and titanium oxide coating deposited by electrophoretic method on ti-13Nb-13Zr alloy. Surf Eng2025; 41: 1080–1090.
22.
SporerEMSchillingCTaitRJ, et al.Strains on the human femur after revision total knee arthroplasty: an in vitro study using digital image correlation. PLoS One2024; 19: e0305387.
23.
LiuRQianDChenY, et al.Investigation of normal knee kinematics in walking and running at different speeds using a portable motion analysis system. Sports Biomech2021; 23: 1–14.
24.
XuYChenYZhouD, et al.Fabrication of TiN coatings deposited on laser shock micro-textured substrates for improving the interface adhesion properties of coatings. Materials (Basel)2024; 17: 3332.
25.
AhmedSDePaivaYAmorimJM, , et al.Laser surface texturing and characterization of austenitic stainless steel for the improvement of its surface properties. The International Journal of Advanced Manufacturing Technology2021; 115: 1795–1808.
26.
GuptaRGaddamAPrajapatiD, et al.Enhancing bactericidal properties of Ti6Al4 V surfaces through micro- and nano-hierarchical laser texturing. Langmuir2024; 40: 16791–16803.
27.
YilmazerH. Physical vapor deposited TiN and TiAlN coatings on biomedical β-type ti-29Nb-13Ta-4.6Zr: microstructural characteristics, surface hardness enhancement and antibacterial activity. Coatings2025; 15: 1126.
28.
NagarajanBYildirimKSaravananR, et al.Laser surface texturing for antiviral surfaces?Journal of Micro and Nano-Manufacturing2021; 9: 031003.
