Abstract:High doses of antimicrobial agents are a huge threat due to the increasing number of pathogenic organisms that are becoming resistant to antimicrobial agents. This resistance has led to a search for alternatives. Therefore, this study presents the synthesis and characterization of ZrO2-Ag2O nanoparticles (NPs) by sol-gel. The NPs were analyzed by dynamic light scattering (DLS), UV-visible (UV-vis), Raman and scanning electron microscopy (SEM). The NPs were later evaluated for their antifungal effects against C… Show more
“…Silver oxide nanoparticles penetrate the cell wall and cytoplasmic membrane by binding to lipids and proteins, leading to cell lysis and toxic effects inside the cell (Fig. 8 ) 66 . The mechanisms of antifungal activity of Ag 2 O NPs can be attributed to the production of reactive oxygen species (Fig.…”
Section: Resultsmentioning
confidence: 99%
“…8 B). Consequently, these nanoparticles negatively affect the expression of the oxidative enzyme, thereby causing the inability to handle the resulting stress 66 . Figure 8 Schematic illustration of antibacterial ( A ) and antifungal ( B ) activity of Ag 2 O nanoparticles.…”
Section: Resultsmentioning
confidence: 99%
“…Additionally, these nanoparticles can have antifungal properties by disturbing the antioxidant endogenic process and unsettling the pathogen's internal environment. They can also alter homeostatic redox reactions and oxidative stress, leading to an imbalance in osmotic pressure, membrane destruction, and ultimately cell death 66 . These nanoparticles enhance their antifungal effect by inhibiting the enzymatic activity of various enzymes, such as the activity of transferase in lecithin or ATPase in P-glycoprotein 66 .…”
Section: Resultsmentioning
confidence: 99%
“…They can also alter homeostatic redox reactions and oxidative stress, leading to an imbalance in osmotic pressure, membrane destruction, and ultimately cell death 66 . These nanoparticles enhance their antifungal effect by inhibiting the enzymatic activity of various enzymes, such as the activity of transferase in lecithin or ATPase in P-glycoprotein 66 . They arrest the fungal cell cycle by increasing the percentage of cells in G2/M phase and decreasing them significantly in G1 phase 64 .…”
Section: Resultsmentioning
confidence: 99%
“…8B). Consequently, these nanoparticles negatively affect the expression of the oxidative enzyme, thereby causing the inability to handle the resulting stress 66 .…”
Silver oxide nanoparticles have various biomedical and pharmaceutical applications. However, conventional nanofabrication of Ag2O is associated with the use of toxic chemicals and organic solvents. To circumvent this hurdle, herein silver oxide quantum dots (Ag2O-QDs) were synthesized quickly (3 min) via the use of ultrasonic irradiation and plant-extract. Additionally, due to ultrasonic irradiation's effect on cell-wall destruction and augmentation of extraction efficiency, ultrasonic was also used in the preparation of Mentha pulegium and Ficus carica extracts (10 min, r.t) as natural eco-friendly reducing/capping agents. The UV–Vis result indicated a broad absorption peak at 400–500 nm. TEM/SEM analysis showed that ultrasound introduced a uniform spherical particle and significantly reduced particle size compared to the conventional heating method (∼ 9 nm vs. ∼ 100 nm). Silver and oxygen elements were found in the bio-synthesized Ag2O by EDS. The FTIR and phenol/flavonoid tests revealed the presence of phenol and flavonoid associated with the nanoparticles. Moreover, nanoparticles exhibited antioxidant/antibacterial/antifungal activities. The MIC and MBC results showed the Ag2O QDs synthesized with M. pulegium extract have the highest antibacterial activity against E. coli (MBC = MIC:15.6 ppm), which were significantly different from uncoated nanoparticles (MBC = MIC:500 ppm). The data reflects the role of phyto-synthesized Ag2O-QDs using ultrasonic-irradiation to develop versatile and green biomedical products.
“…Silver oxide nanoparticles penetrate the cell wall and cytoplasmic membrane by binding to lipids and proteins, leading to cell lysis and toxic effects inside the cell (Fig. 8 ) 66 . The mechanisms of antifungal activity of Ag 2 O NPs can be attributed to the production of reactive oxygen species (Fig.…”
Section: Resultsmentioning
confidence: 99%
“…8 B). Consequently, these nanoparticles negatively affect the expression of the oxidative enzyme, thereby causing the inability to handle the resulting stress 66 . Figure 8 Schematic illustration of antibacterial ( A ) and antifungal ( B ) activity of Ag 2 O nanoparticles.…”
Section: Resultsmentioning
confidence: 99%
“…Additionally, these nanoparticles can have antifungal properties by disturbing the antioxidant endogenic process and unsettling the pathogen's internal environment. They can also alter homeostatic redox reactions and oxidative stress, leading to an imbalance in osmotic pressure, membrane destruction, and ultimately cell death 66 . These nanoparticles enhance their antifungal effect by inhibiting the enzymatic activity of various enzymes, such as the activity of transferase in lecithin or ATPase in P-glycoprotein 66 .…”
Section: Resultsmentioning
confidence: 99%
“…They can also alter homeostatic redox reactions and oxidative stress, leading to an imbalance in osmotic pressure, membrane destruction, and ultimately cell death 66 . These nanoparticles enhance their antifungal effect by inhibiting the enzymatic activity of various enzymes, such as the activity of transferase in lecithin or ATPase in P-glycoprotein 66 . They arrest the fungal cell cycle by increasing the percentage of cells in G2/M phase and decreasing them significantly in G1 phase 64 .…”
Section: Resultsmentioning
confidence: 99%
“…8B). Consequently, these nanoparticles negatively affect the expression of the oxidative enzyme, thereby causing the inability to handle the resulting stress 66 .…”
Silver oxide nanoparticles have various biomedical and pharmaceutical applications. However, conventional nanofabrication of Ag2O is associated with the use of toxic chemicals and organic solvents. To circumvent this hurdle, herein silver oxide quantum dots (Ag2O-QDs) were synthesized quickly (3 min) via the use of ultrasonic irradiation and plant-extract. Additionally, due to ultrasonic irradiation's effect on cell-wall destruction and augmentation of extraction efficiency, ultrasonic was also used in the preparation of Mentha pulegium and Ficus carica extracts (10 min, r.t) as natural eco-friendly reducing/capping agents. The UV–Vis result indicated a broad absorption peak at 400–500 nm. TEM/SEM analysis showed that ultrasound introduced a uniform spherical particle and significantly reduced particle size compared to the conventional heating method (∼ 9 nm vs. ∼ 100 nm). Silver and oxygen elements were found in the bio-synthesized Ag2O by EDS. The FTIR and phenol/flavonoid tests revealed the presence of phenol and flavonoid associated with the nanoparticles. Moreover, nanoparticles exhibited antioxidant/antibacterial/antifungal activities. The MIC and MBC results showed the Ag2O QDs synthesized with M. pulegium extract have the highest antibacterial activity against E. coli (MBC = MIC:15.6 ppm), which were significantly different from uncoated nanoparticles (MBC = MIC:500 ppm). The data reflects the role of phyto-synthesized Ag2O-QDs using ultrasonic-irradiation to develop versatile and green biomedical products.
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