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• W3194739422 abstract "Antibiotics have been the nucleus of chemotherapy since their discovery and introduction into the healthcare system in the 1940s. They are routinely used to treat bacterial infections and to prevent infections in patients with compromised immune systems and enhancing growth in livestock. However, resistance to last-resort antibiotics used in the treatment of multidrug-resistant infections has been reported worldwide. Therefore, this study aimed to evaluate green synthesized nanomaterials such as silver nanoparticles (AgNPs) as alternatives to antibiotics. UV-vis spectroscopy surface plasmon resonance peaks for AgNPs were obtained between 417 and 475 nm. An X-ray diffraction analysis generated four peaks for both Prunus africana extract (PAE) and Camellia sinensis extract (CSE) biosynthesized AgNPs positioned at 2θ angles of 38.2°, 44.4°, 64.5°, and 77.4° corresponding to crystal planes (111), (200), (220), and (311), respectively. A dynamic light-scattering analysis registered the mean zeta potential of +6.3 mV and +0.9 mV for PAE and CSE biosynthesized nanoparticles, respectively. Fourier transform infrared spectroscopy spectra exhibited bands corresponding to different organic functional groups confirming the capping of AgNPs by PAE and CSE phytochemicals. Field emission scanning electron microscopy imaging showed that AgNPs were spherical with average size distribution ranging from 10 to 19 nm. Biosynthesized AgNPs exhibited maximum growth inhibitory zones of 21 mm with minimum inhibitory concentration and minimum bactericidal concentration of 125 and 250 μg/ml, respectively, against carbapenem-resistant bacteria." @default.
• W3194739422 created "2021-08-30" @default.
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• W3194739422 date "2021-08-24" @default.
• W3194739422 modified "2023-10-11" @default.
• W3194739422 title "Green Strategy–Based Synthesis of Silver Nanoparticles for Antibacterial Applications" @default.
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• W3194739422 cites W1830032345 @default.
• W3194739422 cites W1830337001 @default.
• W3194739422 cites W1964025651 @default.
• W3194739422 cites W1965417239 @default.
• W3194739422 cites W1968212840 @default.
• W3194739422 cites W1968284364 @default.
• W3194739422 cites W1970464014 @default.
• W3194739422 cites W1971077105 @default.
• W3194739422 cites W1973658327 @default.
• W3194739422 cites W1977108112 @default.
• W3194739422 cites W1978551709 @default.
• W3194739422 cites W1984499615 @default.
• W3194739422 cites W1989412579 @default.
• W3194739422 cites W1995049685 @default.
• W3194739422 cites W1998651898 @default.
• W3194739422 cites W2000201313 @default.
• W3194739422 cites W2003258997 @default.
• W3194739422 cites W2006097695 @default.
• W3194739422 cites W2008122854 @default.
• W3194739422 cites W2008461092 @default.
• W3194739422 cites W2028344143 @default.
• W3194739422 cites W2031056779 @default.
• W3194739422 cites W2036460798 @default.
• W3194739422 cites W2049136420 @default.
• W3194739422 cites W2052959312 @default.
• W3194739422 cites W2061651826 @default.
• W3194739422 cites W2064401609 @default.
• W3194739422 cites W2072567873 @default.
• W3194739422 cites W2085361768 @default.
• W3194739422 cites W2093897877 @default.
• W3194739422 cites W2096420970 @default.
• W3194739422 cites W2112565136 @default.
• W3194739422 cites W2116044020 @default.
• W3194739422 cites W2139313215 @default.
• W3194739422 cites W2148260760 @default.
• W3194739422 cites W2156122171 @default.
• W3194739422 cites W2163268282 @default.
• W3194739422 cites W2163531942 @default.
• W3194739422 cites W2172702989 @default.
• W3194739422 cites W2322747470 @default.
• W3194739422 cites W2328745402 @default.
• W3194739422 cites W2330446751 @default.
• W3194739422 cites W2348633387 @default.
• W3194739422 cites W2411825092 @default.
• W3194739422 cites W2461980586 @default.
• W3194739422 cites W2552642879 @default.
• W3194739422 cites W2562717314 @default.
• W3194739422 cites W2588873682 @default.
• W3194739422 cites W2589067428 @default.
• W3194739422 cites W2749005698 @default.
• W3194739422 cites W2767749087 @default.
• W3194739422 cites W2790415230 @default.
• W3194739422 cites W2883118599 @default.
• W3194739422 cites W2887348860 @default.
• W3194739422 cites W2896218029 @default.
• W3194739422 cites W2899246795 @default.
• W3194739422 cites W2901471691 @default.
• W3194739422 cites W2902016396 @default.
• W3194739422 cites W2921510581 @default.
• W3194739422 cites W2964247574 @default.
• W3194739422 cites W2971716367 @default.
• W3194739422 cites W2972586133 @default.
• W3194739422 cites W2998144666 @default.
• W3194739422 cites W3016463754 @default.
• W3194739422 cites W3025858399 @default.
• W3194739422 cites W3045341266 @default.
• W3194739422 cites W3057541719 @default.
• W3194739422 cites W3095351157 @default.
• W3194739422 cites W3110883955 @default.
• W3194739422 cites W3113368980 @default.
• W3194739422 cites W3118416357 @default.
• W3194739422 cites W3120089379 @default.
• W3194739422 cites W3122317501 @default.
• W3194739422 cites W3135681121 @default.
• W3194739422 cites W3148255637 @default.
• W3194739422 cites W3200318313 @default.
• W3194739422 cites W4205094190 @default.
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• W3194739422 doi "https://doi.org/10.3389/fnano.2021.697303" @default.
• W3194739422 hasPublicationYear "2021" @default.
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