Novel nano-thin amorphous Ta-coating on 3D-printed porous TC4 implant: Microstructure and enhanced biological effects
Puquan Wang, Shilong Mao, Jiao Yan, Weijian Wang, Jiaxin Yu, Yanfeng Luo, Xiaohong Li, Fuyou Wang
Abstract
A nano-thin amorphous Ta-coating in the order of 20 nm was successfully deposited on the 3D-printed TC4 implant utilizing magnetron sputtering with reasonable process parameters. This amorphous Ta-coating with trace amounts of oxidation ensures robust interfacial bonding without shedding and high coverage within the porous scaffold, exhibits superior cell proliferation and bone ingrowth effects compared to TC4 and pure Ta implants, suggesting cost-efficient and excellent biological performance material that could potentially replace TC4 to repair bone defects. • A nano-thin amorphous Ta-coating is successfully deposited on the 3D-printed TC4 implant. • The multilayer interface consists of surface TaO x , Ta-coating, hybrid TaO x and TiO x , and an impact-refinement nanocrystalline TC4 zone. • Interfacial bonding is strengthened through the solid solution of oxygen and interfacial densification of amorphous-crystalline bonding and impact compression. • Ta-coating exhibits superior bone ingrowth effects compared to TC4 and pure Ta implants, suggesting its potential as a cost-effective material for repairing bone defects. Bone defects caused by tumors, trauma, or other bone diseases are common in clinical practice. Titanium alloy (TC4) and tantalum (Ta) are the primary metallic materials for bone repair. However, TC4 frequently suffers from poor osseointegration and implant loosening, while the high cost of Ta limits its widespread use for reconstructing large bone defects. To address this issue, this research employs magnetron sputtering (MSP) to deposit a nano-thin amorphous Ta-coating on the 3D-printed TC4 implant. SEM examinations of compressed samples show robust interfacial bonding without shedding, while the presence of Ta within the porous structure indicates high coverage. High-resolution TEM analysis first reveals a distinct multilayer amorphous zone consisting of surface TaO x , Ta-coating, and hybrid TaO x and TiO x , along with an impact-refinement nanocrystalline TC4 zone. Insufficient energy leads to the formation of amorphous layers. Meanwhile, interfacial bonding is strengthened through the solid solution of oxygen and interfacial densification of amorphous-crystalline bonding and impact compression. Biological evaluations demonstrate that the Ta-coating exhibits superior cell proliferation and bone ingrowth effects compared to TC4 and pure Ta implants, primarily attributed to the amorphous oxide composition on the surface. This study offers novel, cost-efficient, and excellent biological performance materials for bone defect implants.