Abstract
Green synthesis has gained a wide recognition as clean synthesis technique in the recent years. In the present investigation, silver nanoparticles were prepared by a novel green synthesis technique using Mangifera indica (Mango leaves) and found to be successfully used in dental applications. The prepared samples were spectroscopically characterized by XRD, PSA, SEM with EDS, and UV–Vis spectroscopy. The crystalline size and lattice strain were analyzed from the XRD data which were counter-verified by W–H plots and particle size analyzer. The XRD peaks revealed that average crystalline size of the as-synthesized Ag nanoparticles was of 32.4 nm with face-centered cubic structure. This was counter-verified by particle size analyzer and Williamson–Hall plots and found to be 31.7 and 33.21 nm in the former and latter, and the crystalline size of Ag NPs could be concluded as 32 ± 2 nm. The morphological structure of the prepared sample was studied through SEM images and the chemical composition was analyzed by the EDS data. The band energy was calculated as 393 nm from UV–Vis, which confirmed the synthesized sample as Ag nanoparticles. To improve the mechanical bonding and hardness of the dentally used glass ionomer cement (GIC), the synthesized silver nanoparticles were incorporated into GIC in 2% weight ratio. The morphology of the prepared specimens was studied using optical microscope images. Vickers microhardness and Monsanto hardness tests were performed on GIC, GIC reinforced with microsilver particles and GIC reinforced with nanosilver particles and the latter derived a promising results. The results of the Monsanto tests confirmed the increase in hardness of the GIC reinforced with AgNps as 14.2 kg/cm2 compared to conventional GIC and GIC reinforced with silver microparticle as 11.7 and 9.5 kg/cm2. Similarly the Vickers hardness results exhibited the enhanced hardness of GIC-reinforced AgNps as 82 VHN compared to GIC as 54 and GIC-reinforced silver microparticles as 61 VHN. The antibacterial activity of AgNPs was tested by a well-diffusion method on Escherichia coli and Staphylococcus aureus bacteria, and the obtained results exhibited a promising antibacterial activity of the as-synthesized nanoparticles.
Highlights
The fascinating size of 1–100 nm is dealt with nanotechnology which has gained a wider interest in the research field
The crystalline size calculated from Particle Size Analyzer (PSA) is further counterverified by Powder X-ray diffraction (PXRD) and Williamson–Hall plots
Silver nanoparticles were synthesized by a novel green synthesis technique using fresh Mangifera indica and characterized to evaluate the crystalline size, shape, crystalline imperfection and Concentration of AgNPs
Summary
The fascinating size of 1–100 nm is dealt with nanotechnology which has gained a wider interest in the research field. Nanotechnology has become a useful tool in medical field for its extensive applications in several forms. Metal nanoparticles are always enhanced for their unique properties and potential applications in the engineering and. The study of AgNPs is concentrated due to their antibacterial activity (Kim et al 2007; Shahverdi et al 2007) and dental applications (Garcıa-Contreras et al 2011). AgNps are used in various applications such as nanosensors due to their excellent electrochemical properties (Manno et al 2008), halloysite nanotubes (HNTs) (Liu and Zhao 2009), catalyst (Guo et al 2008), textile industry, water treatment (Dankovich and Gray 2011) optical data storage (Kelly et al 2003), fluorescent emissions in biological labels and electroluminescent displays (Mulvaney 1996; Berciaud et al 2005)
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