Restricted accessResearch articleFirst published online 2026
Effects of hydrothermal treatment time on the release kinetics of Ni 2+ and Zn 2+,corrosion behavior and biological properties of Zn-supported Ni-Ti-O nanopores coatings
Bone implant materials with excellent corrosion resistance, antibacterial property, and controlled ion release kinetics are crucial for their clinical application. In this study, Zn-supported Ni-Ti-O nanopores (NPs) coating was prepared on the surface of nickel-titanium (NiTi) implants by anodization and hydrothermal treatment (HT), the effects of HT time on coatings structure, antibacterial property, corrosion resistance, Ni2+ and Zn2+ release behavior and biocompatibility were studied. The results indicate that with the extension of HT time, the coating thickness increases, while the diameters of the NPs decrease. After 3 h of HT, the average diameter of the NPs is 42.52 nm, which is about 1/2 of that after anodization (86.63 nm). Furthermore, our experimental results show that with the extension of HT time, the corrosion resistance is improved, and the corrosion current density of the sample NP-30-Zn-3h is 3.214 × 10−8 A⋅cm−2, which is one order of magnitude lower than that of the NiTi substrate (7.529 × 10−7 A⋅cm−2). In addition, Zn-supported Ni-Ti-O NPs coatings exhibit excellent antibacterial property and biocompatibility, especially the sample NP-30-Zn-3h. Interestingly, with the extension of HT time, the release of Ni2+ and Zn2+ is inhibited, and Zn2+ concentration released from the sample NP-30-Zn-3h is about 3.65 mg/L at days 7 and 14, which is close to the reported osteoblast-stimulating concentration of 3.53 mg/L.
PrabuSMAravindanSGhoshS, et al.Solid-state welding of nitinol shape memory alloys: a review. Mater Today Commun2023; 35: 23.
2.
AgarwalNRyan MurphyJHashemiTS, et al.Effect of heat treatment time and temperature on the microstructure and shape memory properties of nitinol wires. Materials2023; 16: 64.
3.
KhanlariEShiQYanX, et al.Printing of NiTinol parts with characteristics respecting the general microstructural, compositional and mechanical requirements of bone replacement implants. Mater Sci Eng, A2022; 839: 142839.
4.
MarkhoffJKrogullMSchulzeC, et al.Biocompatibility and inflammatory potential of titanium alloys cultivated with human osteoblasts, fibroblasts and macrophages. Materials2017; 10: 1996.
5.
ZhangJ-MSunY-HZhaoY, et al.Antibacterial ability and cytocompatibility of Cu-incorporated Ni–Ti–O nanopores on NiTi alloy. Rare Met2019; 38: 552.
6.
SoltanalipourMKhalil-AllafiJ. Preparation of tantalum-containing coatings on NiTi shape memory alloys with enhanced in vitro cytocompatibility and antibacterial effectiveness. J Mater Res Technol2024; 30: 8419.
7.
LuoXYangCLiD, et al.Laser powder bed fusion of beta-type titanium alloys for biomedical application: a review. Acta Metall Sin2024; 37: 17.
8.
LiuZRenD-CZhangL-M, et al.Synergistic improvement in ductility and hot nitric acid corrosion resistance of LPBF Ti-6Al-4V alloy via hot isostatic pressing. Acta Metall Sin2025; 38: 102–106.
9.
JaishankarMTsetenTAnbalaganN, et al.Toxicity, mechanism and health effects of some heavy metals, Beeregowda. Interdiscip Toxicol2014; 7: 60.
10.
GaoJXinYBaiJ, et al.Well-adhered Ti alloying layer on NiTi alloy: surface Ni content, corrosion resistance, and cytocompatibility. J Mater Eng Perform2024; 8: 15.
11.
ZhouYWangTLuP, et al.Exploring the potential of MIM-manufactured porous NiTi as a vascular drug delivery materia. Ann Biomed Eng2024; 9: 1573.
12.
LiKGengWZhaoW, et al.Design and development of titanium-coated implants with advanced antioxidant properties for enhanced regenerative repair of diabetic bone. Chem Eng J2024; 497: 154522.
13.
WangFZhangYChenX, et al.Biocompatible Ti-O film prepared on NiTi alloy by plasma immersion ion implantation and deposition. Colloids Surf B Biointerfaces2016; 143: 390.
14.
SunYZhaoYZhangH, et al.Corrosion behavior, antibacterial ability, and osteogenic activity of Zn-incorporated Ni-Ti-O nanopore layers on NiTi alloy. J Mater Sci Technol2022; 97: 69.
15.
ZhangSLiangJLiuY. Excessive zinc ion caused pc12 cell death correlating with inhibition of NOS and increase of RAGE in cells. Cell Biochem Biophys2022; 80: 755.
16.
HangRZongMBaiL, et al.Anodic growth of ultra-long Ni-Ti-O nanopores. Electrochem Commun2016; 71: 28.
17.
ZhaoLWangHHuoK, et al.Antibacterial nano-structured titania coating incorporated with silver nanoparticles. Biomaterials2011; 32: 5706.
18.
LiuYRenZBaiL, et al.Relationship between Ni release and cytocompatibility of Ni-Ti-O nanotubes prepared on biomedical NiTi alloy. Corros Sci2017; 123: 209.
19.
JiangDXiaXHouJ, et al.A novel coating system with self-reparable slippery surface and active corrosion inhibition for reliable protection of Mg alloy. Chem Eng J2019; 373: 285.
20.
DongYLiJXuD, et al.Investigation of microbial corrosion inhibition of Cu-bearing 316L stainless steel in the presence of acid producing bacterium Acidithiobacillus caldus SM-1. J Mater Sci Technol2021; 64: 176.
21.
LiDLinCBatchelor-McauleyC, et al.Tafel analysis in practice. J Electroanal Chem2018; 826: 117.
22.
SunYRongYZhaoY, et al.Electrochemical stability, corrosion behavior, and biological properties of Ni–Ti–O nanoporous layers anodically on NiTi alloy. Corros Sci2021; 179: 109104.
23.
WengZBaiLLiuY, et al.Osteogenic activity, antibacterial ability, and Ni release of Mg-incorporated Ni-Ti-O nanopore coatings on NiTi alloy. Appl Surf Sci2019; 486: 441.
24.
GhoshGSidparaABandyopadhyayPP. Understanding the role of surface roughness on the tribological performance and corrosion resistance of WC-Co coating. Surf Coating Technol2019; 378: 50.
25.
HangRLiuSLiuY, et al.Preparation, characterization, corrosion behavior and cytocompatibility of NiTiO3 nanosheets hydrothermally synthesized on biomedical NiTi alloy. Mater Sci Eng C2019; 97: 715.
HuangS-MLiuS-MChenW-C, et al.Advances of hydroxyapatite hybrid organic composite used as drug or protein carriers for biomedical applications: a review. Pharmaceuticals2022; 15: 78.
28.
KumarRUmarAKumarG, et al.Antimicrobial properties of ZnO nanomaterials: a review. Ceram Int2017; 43: 3940.
29.
ShenYShanXEtimIP, et al.Comparative study of the effects of nano ZnO and CuO on the biodegradation, biocompatibility, and antibacterial properties of micro-arc oxidation coating of magnesium alloy. Acta Metall Sin2024; 37: 242.
30.
DiRSunYYaoR, et al.Preparation of TiO2 nano-flower coating on Ti substrates with good physical sterilization effect and biocompatibility. Acta Metall Sin2024; 37: 1581.
31.
IkeuchiMItoADohiY, et al.Osteogenic differentiation of cultured rat and human bone marrow cells on the surface of zinc‐releasing calcium phosphate ceramics. J Biomed Mater Res A2003; 67: 15.
32.
MengGWuXYaoR, et al.Effect of zinc substitution in hydroxyapatite coating on osteoblast and osteoclast differentiation under osteoblast/osteoclast co-culture. Regen Biomater2019; 6: 349.
33.
ItoAOjimaKNaitoH, et al.Preparation, solubility, and cytocompatibility of zinc‐releasing calcium phosphate ceramics. J Biomed Mater Res2000; 50: 178.
34.
NagataMLönnerdalB. Role of zinc in cellular zinc trafficking and mineralization in a murine osteoblast-like cell line. J Nutr Biochem2011; 22: 172.
