Biological Property Investigation of Nitinol Surface Implanted with Tantalum

Ling WU; Ji TAN; Shi QIAN; Naijian GE; Xuanyong LIU

doi:10.15541/jim20220140

[1] Report on cardiovascular health and diseases burden in China:an updated summary of 2020. Chinese Circulation Journal, 582-590(2021).

[2] J L BRASH, T A HORBETT, R A LATOUR et al. The blood compatibility challenge. Part 2: protein adsorption phenomena governing blood reactivity. Acta Biomaterialia(2019).

[3] L JIANG, H YAO, X LUO et al. Copper-mediated synergistic catalytic titanium dioxide nanofilm with nitric oxide generation and anti-protein fouling for enhanced hemocompatibility and inflammatory modulation. Applied Materials Today(2020).

[4] M A SUROVTSEVA, O V POVESCHENKO, O S KUZMIN et al. Titanium oxide- and oxynitride-coated nitinol: effects of surface structure and composition on interactions with endothelial cells. Applied Surface Science(2022).

[5] Y ZHAO, Z WANG, L BAI et al. Regulation of endothelial functionality through direct and immunomodulatory effects by Ni-Ti-O nanospindles on NiTi alloy. Materials Science & Engineering C-Materials for Biological Applications(2021).

[6] I COCKERILL, C W SEE, M L YOUNG et al. Designing better cardiovascular stent materials: a learning curve. Advanced Functional Materials, 2005361-23(2021).

[7] A M CHERIAN, S V NAIR, V MANIYAL et al. Surface engineering at the nanoscale: a way forward to improve coronary stent efficacy. APL Bioengineering, 1508-23(2021).

[8] Y L LAI, P Y CHENG, C C YANG et al. Electrolytic deposition of hydroxyapatite/calcium phosphate-heparin/gelatin-heparin tri-layer composites on NiTi alloy to enhance drug loading and prolong releasing for biomedical applications. Thin Solid Films(2018).

[9] D WANG, F PENG, J LI et al. Butyrate-inserted Ni-Ti layered double hydroxide film for H₂O₂-mediated tumor and bacteria killing. Materials Today, 238-257(2017).

[10] Y QI, H QI, Y HE et al. Strategy of metal-polymer composite stent to accelerate biodegradation of iron-based biomaterials. ACS Applied Materials & Interfaces, 182-192(2018).

[11] Y ZHAO, Y H SUN, W W LAN et al. Self-assembled nanosheets on NiTi alloy facilitate endothelial cell function and manipulate macrophage immune response. Journal of Materials Science & Technology(2021).

[12] H YU, Y LIU, Y WANG et al. A study on poly (N-vinyl-2- pyrrolidone) covalently bonded NiTi surface for inhibiting protein adsorption. Progress in Natural Science-Materials International, 584-589(2016).

[13] D ZANG, H YI, Z GU et al. Interfacial engineering of hierarchically porous NiTi/hydrogels nanocomposites with exceptional antibiofouling surfaces. Advanced Materials, 1602869-7(2017).

[14] H QIU, P QI, J LIU et al. Biomimetic engineering endothelium- like coating on cardiovascular stent through heparin and nitric oxide-generating compound synergistic modification strategy. Biomaterials(2019).

[15] F MOHAMMADI, N GOLAFSHAN, M KHARAZIHA et al. Chitosan-heparin nanoparticle coating on anodized NiTi for improvement of blood compatibility and biocompatibility. International Journal of Biological Macromolecules(2019).

[16] F WANG, Y ZHANG, X M CHEN et al. ALD mediated heparin grafting on nitinol for self-expanded carotid stents. Colloids and Surfaces B-Biointerfaces, 143:(2016).

[17] L C SU, Y H CHEN, M C CHEN. Dual drug-eluting stents coated with multilayers of hydrophobic heparin and sirolimus. ACS Applied Materials & Interfaces, 12944-12953(2013).

[18] C PARK, S W LEE, J KIM et al. Reduced fibrous capsule formation at nano-engineered silicone surfaces via tantalum ion implantation. Biomaterials Science, 2907-2919(2019).

[19] C PARK, S PARK, J KIM et al. Enhanced endothelial cell activity induced by incorporation of nano-thick tantalum layer in artificial vascular grafts. Applied Surface Science(2020).

[20] C PARK, Y J SEONG, I G KANG et al. Enhanced osseointegration ability of poly(lactic acid) via tantalum sputtering-based plasma immersion ion implantation. ACS Applied Materials & Interfaces, 10492-10504(2019).

[21] S L ZHU, X J YANG, D H FU et al. Stress-strain behavior of porous NiTi alloys prepared by powders sintering. Materials Science and Engineering Structural Materials Properties Microstructure and Processing, 264-268(2005).

[22] H WAKABAYASHI, T SAN-NO, T TORIYAMA et al. The effect of temperature during helium ion implantation-induced crystallization of iron-based amorphous alloys. 14th International Conference on Ion Implantation Technology, Taos, New Mexico(2003).

[23] M ZIER, S OSWALD, R REICHE et al. XPS investigations of thin tantalum films on a silicon surface. Analytical and Bioanalytical Chemistry Research, 902-905(2003).

[24] X GENG, W XU, P WANG et al. Enhanced photocatalytic activity of nonstoichiometric crystalline TaO₂F and Ta₂O₅ with carbon coating. Ceramics International, 1857-1868(2022).

[25] R SIMPSON, R G WHITE, J F WATTS. XPS investigation of monatomic and cluster argon ion sputtering of tantalum pentoxide. Applied Surface Science, 405:(2017).

[26] O BIKONDOA, C L PANG, R ITHNIN et al. Direct visualization of defect-mediated dissociation of water on TiO₂(110). Nature Materials, 189-192(2006).

[29] Y ZHUANG, C ZHANG, M CHENG et al. Challenges and strategies for in situ endothelialization and long-term lumen patency of vascular grafts. Bioactive Materials, 1791-1809(2021).

[30] N LYU, Z DU, H QIU et al. Mimicking the nitric oxide-releasing and glycocalyx functions of endothelium on vascular stent surfaces. Advanced Science, 2002330-12(2020).

[31] T ZHAO, Y LI, Y GAO et al. Hemocompatibility investigation of the NiTi alloy implanted with tantalum. Journal of Materials Science-Materials in Medicine, 2311-2318(2011).