Molecular insights into quercetin-enhanced crystalline silver nanoparticles: Implications for breast cancer cell cytotoxicity and antibacterial action in Kyllinga nemoralis

Abstract

Amidst the ongoing global health crisis posed by cancer and antibiotic-resistant infections, innovative solutions are in high demand. The utilization of Kyllinga nemoralis leaf (KNL) extracts for synthesizing silver nanoparticles (AgNPs) represents a novel approach, with the potential to deliver profound advancements in healthcare, benefitting society on a broad scale. Successful synthesis of AgNPs by KNL extracts for treating breast cancer cells, specifically MDA-MB-231 cells, is recorded in this report. The adsorption mechanism of quercetin (Q) on Ag and its optimized structural characteristics were computed at the DFT level. According to FTIR analysis, quercetin, one of the flavonoids found in KNL extract, acts as a reducing and stabilizing agent for the conversion of Ag+ ions to Ag0, and carboxylates serve as ligands that cap the AgNPs. The small-sized (7 nm), spherical particles, which are uniform in size and monodispersed, exhibit regulation over the size of the AgNPs due to being shielded by enough flavonoids and gallic acid absorbed into the extract. The observed negative zeta potential of −20 mV indicates the moderate stability of the AgNPs colloid. It is noted that AgNPs prepared at higher concentrations of KNL extract showed lower minimum inhibitory concentration (MIC) values (80 µg/mL) and larger inhibition zones (22 mm) against Pseudomonas aeruginosa. The cell viability rate of MDA-MB-231 cell lines decreases with increasing concentration of AgNPs. The antibacterial and anticancer activity of AgNPs is observed in a size-dependent manner. This research raises the possibility of using plant-based, small-sized AgNPs therapeutically for breast cancer and as antibacterial agents.