1. Friction Stir Processing of Stainless Steel for Ascertaining Its Superlative Performance in Bioimplant Applications
- Author
-
Sundeep Mukherjee, Deepika Kannan, Shailja Singh, H.S. Grewal, Amrita Chakrabarti, Aditya Ayyagari, Harpreet Singh Arora, Soumya Pati, and Gopinath Perumal
- Subjects
Materials science ,Friction stir processing ,Passivation ,Friction ,Surface Properties ,Simulated body fluid ,Alloy ,02 engineering and technology ,Surface engineering ,engineering.material ,010402 general chemistry ,01 natural sciences ,Corrosion ,Materials Testing ,General Materials Science ,Metallurgy ,technology, industry, and agriculture ,Reproducibility of Results ,021001 nanoscience & nanotechnology ,Stainless Steel ,Grain size ,0104 chemical sciences ,engineering ,Severe plastic deformation ,0210 nano-technology - Abstract
Substrate-cell interactions for a bioimplant are driven by substrate's surface characteristics. In addition, the performance of an implant and resistance to degradation are primarily governed by its surface properties. A bioimplant typically degrades by wear and corrosion in the physiological environment, resulting in metallosis. Surface engineering strategies for limiting degradation of implants and enhancing their performance may reduce or eliminate the need for implant removal surgeries and the associated cost. In the current study, we tailored the surface properties of stainless steel using submerged friction stir processing (FSP), a severe plastic deformation technique. FSP resulted in significant microstructural refinement from 22 μm grain size for the as-received alloy to 0.8 μm grain size for the processed sample with increase in hardness by nearly 1.5 times. The wear and corrosion behavior of the processed alloy was evaluated in simulated body fluid. The processed sample demonstrated remarkable improvement in both wear and corrosion resistance, which is explained by surface strengthening and formation of a highly stable passive layer. The methylthiazol tetrazolium assay demonstrated that the processed sample is better in supporting cell attachment, proliferation with minimal toxicity, and hemolysis. The athrombogenic characteristic of the as-received and processed samples was evaluated by fibrinogen adsorption and platelet adhesion via the enzyme-linked immunosorbent assay and lactate dehydrogenase assay, respectively. The processed sample showed less platelet and fibrinogen adhesion compared with the as-received alloy, signifying its high thromboresistance. The current study suggests friction stir processing to be a versatile toolbox for enhancing the performance and reliability of currently used bioimplant materials.
- Published
- 2017